Directly Measuring the Adhesive and Elastic Properties of Bacteria using a Surface Force Apparatus

Heo, Cheol Ho

January 2006

Bacterial adhesion is the first step of biofilm formation that plays various roles in the environment and the human body. Examples of undesirable roles of biofilm formation include metal rust, sewage sludge and bacteria-related diseases. Desirable roles are biofiltration and bioremediation.For a decade, Atomic Force Microscopy (AFM) has been the primary tool used to study the adhesion and elastic properties of individual bacteria. In this work we show it is possible to use a Surface Forces Apparatus (SFA) to measure elastic and adhesive properties of small collections of surface bound bacteria. The measurements are conducted with incomplete, patterned bacterial films and we have developed a protocol to image the contact area with AFM after the experiment. Using the SFA, we measured the force profile between a P. Aeruginosa PAO1 film and a bare mica surface. We repeated the measurement in the same contact position for up to ten days to determine the effect of desiccation on the film material properties, and then moved to the new contact area to measure the film thickness and elastic properties. A large shrinkage of the bacterial film thickness was measured during the first few days due to the bacterial film desiccation and rearrangement. The proportion of shrinkage depends on factors such as the bacterial film coverage, roughness, temperature and relative humidity. Thickness compressibility was estimated from the force curves. As a force approximation, the stress at the center of the contact (σ) and the area of the contact were estimated by applying the Hertz model. Since the film is incomplete the calculated area in contact was reduced by a factor estimated from the optical image of the contact zone. Adhesiveness was measured in receding force profiles. Maximum adhesive force was detected in the first day, due to the high capillary force, decreased by the bacterial film desiccation and increased again due to the conditioning film.

surface force apparatus

SFA

Multiple Beam Interferometry

bacteria

adhesion

compression

Inverse analysis of the structures of the liquid molecules and colloidal particles near the solid-liquid interfaces: the relation between the number density distribution and the experimental force curve / 固液界面における液体分子とコロイド粒子の構造の逆解析:数密度分布と実験のフォースカーブの関係

Hashimoto, Kota

23 March 2021

京都大学 / 新制・課程博士 / 博士(工学) / 甲第23217号 / 工博第4861号 / 新制||工||1759(附属図書館) / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授 作花 哲夫, 教授 安部 武志, 教授 佐藤 啓文 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Solid-liquid interface

Structural force

Atomic force microscopy

Surface force apparatus

Statistical mechanics of liquid

500

Investigating sub-10 nm-thick Cloaking Films on Sessile Water Droplets Placed on Slippery Lubricant-Infused Porous Surfaces (SLIPS)

Ridwan, Muhammad Ghifari

04 1900

Slippery liquid-infused porous surfaces (SLIPS) – a new class of bio-inspired liquid-repellent surfaces – comprise arbitrarily porous architectures filled with oils that exhibit high interfacial tensions to probe liquids and present ultralow contact angle hysteresis (<〖10〗^°). However, before practical technologies based on SLIPS can be designed at large-scale, a number of fundamental questions remain to be answered. For instance, depending on the sign of the spreading coefficient of the Vapor(V)-lubricant oil(O)-liquid(L) system, defined as S_(OL(V))=γ_LV-γ_LO-γ_OV>0, the lubricating layer forms a layer at the liquid-vapor interface (here, γ_LV is a liquid-vapor interfacial tension, γ_LO – liquid-oil, and γ_OV – oil-vapor). This “cloaking” of liquid drops can deplete SLIPS’ lubricant over time and contaminate the probed liquid. So far, cloaking has been investigated by contact angle goniometry and confocal microscopy, which cannot resolve films of molecular thickness and factors that govern the equilibrium thickness of those films are not entirely clear. Here, we report on the development and application of a reflective-mode SFA platform to characterize the cloaking of water droplets placed on SLIPS. A multilayer matrix method is utilized to analyze the interferometry data. Using this complementary experimental and analytical approach, we determined the thickness of the cloaking layer for the FDTS(solid)-VF-40(lubricant)-water(probe liquid)-air system to be z3= 7±1 nm. Towards deeper insights into the intermolecular and surface forces responsible for cloaking, we demonstrate that repulsive van der Waals interactions are responsible for stabilizing the cloaking film at the water-air interface. Our experimental platform and the analytical framework should facilitate investigations of other SLIPS and probe liquid systems down to the molecular-scale resolution. These findings might aid the rational design of SLIPS, e.g., for drag reduction, anti-biofouling, and anti-corrosion. In addition to investigating SLIPS, We addressed the following questions with the help of atomic force microscopy (AFM): (i) how do zwitterionic osmolytes modulate electrostatic and hydrophobic interactions in nanoscale confinement, and (ii) is it possible to have two negatively charged surfaces attract each other? Our findings are presented as appendices in this thesis.

Infused-liquid surfaces

Surface force apparatus

Interferometer

Cloaking phenomena

Van der Waals interaction

Hamaker constant

Surface and Hydrodynamic Forces in Wetting Films

Pan, Lei

27 August 2013

The process of froth flotation relies on using air bubbles to collect desired mineral particles dispersed in aqueous media on the surface, while leaving undesirous mineral particles behind. For a particle to be collected on the surface of a bubble, the thin liquid films (or wetting films) of water formed in between must rupture. According to the Frumkin-Derjaguin isotherm, it is necessary that wetting films can rupture when the disjoining pressures are negative. However, the negative disjoining pressures are difficult to measure due to the instability and short lifetimes of the films. In the present work, two new methods of determining negative disjoining pressures have been developed. One is to use the modified thin film pressure balance (TFPB) technique, and the other is to directly determine the interaction forces using the force apparatus for deformable surfaces (FADS) developed in the present work. The former is designed to obtain spatiotemporal profiles of unstable wetting films by recording the optical interference patterns. The kinetic information derived from the spatiotemporal profiles were then used to determine the disjoining pressures using an analytical expression derived in the present work on the basis of the Reynolds lubrication theory. The technique has been used to study the effects of surface hydrophobicity, electrolyte (Al3+ ions) concentration, and bubble size on the stability of wetting films. Further, the geometric mean combining rule has been tested to see if the disjoining pressures of the wetting films can be predicted from the disjoining pressures of the colloid films formed between two hydrophobic surfaces and the disjoining pressures of the foam films formed between two air bubbles. The FADS is capable of directly measuring the interaction forces between air bubble and solid surface, and simultaneously monitoring the bubble deformation. The results were analyzed using the Reynolds lubrication theory and the extended DLVO theory to determine both the hydrodynamic and disjoining pressures. The FADS was used to study the effects of surface hydrophobicity and approach speeds. The results show that hydrophobic force is the major driving force for the bubble-particle interactions occurring in flotation. / Ph. D.

wetting film

hydrophobic force

hydrodynamic force

Frumkin-Derjaguin isotherm

Etude des mécanismes de collage des microsystèmes lors de la phase de libération. Mise en oeuvre de moyens de prévention

Raccurt, Olivier

23 June 2004

Les microsystèmes regroupent sur un même substrat des fonctions électroniques, mécaniques, optiques, chimiques ou biologiques et sont fabriqués par les procédés de la microélectronique. Leurs particularités géométriques les rendent extrêmement sensibles aux forces de surfaces qui peuvent conduire à leur collage définitif, notamment lors de l'étape de libération. Cette thèse porte sur la compréhension de ce phénomène. Pour cela une mesure des forces d'adh´esions entre deux surfaces de silicium en milieu liquide a été entreprise à l'aide d'un appareil de mesure des forces de surface et à l'aide de microstructures. L'impact de la tension de surface de différents liquides sur l'adhésion a été étudié. L'étude de la rugosification du silicium par gravure humide, caractérisée par microscope à force atomique ; et l'impact cette rugosité sur l'adhésion a également été menée. Enfin, un procédé industriel original de libération par voie humide sans démouillage des substrats a été développé.

[PHYS:PHYS] Physics/Physics

MEMS

libération

collage

gravure humide

rugosification

Surface Force Apparatus (SFA)

Microscope à force atomique (AFM)

On the Adhesion Between Substrates Covered with Polyelectrolyte Multilayers

Lingström, Rikard

January 2008

This thesis examines the formation of Polyelectrolyte Multilayers (PEM) on cellulose fibres as a new way of influencing the fibre surface and the adhesion between wood fibres. The aim of the study was to enhance the fundamental understanding of the adsorption mechanisms behind the formation of Polyelectrolyte Multilayers on cellulose fibres; to study how the properties of the layers can be influenced and to show how the properties of the layers influence the adhesion between the fibres and the strength of paper sheets made from the PEM treated fibres. Different polyelectrolyte systems are known to form PEMs with different properties, and in this work two different polymer systems were extensively studied: poly(dimethyldiallylammonium chloride) (PDADMAC) / poly(styrene sulphonate) (PSS), which are both strong polylectrolytes (i.e. are highly charged over a wide range of pH) and poly allylaminehydrochloride (PAH) /poly acrylic acid (PAA), which are both weak polyelectorlytes (i.e. sensitive to pH changes). PEMs were also formed from PAH/ poly(3,4-ethylenedioxythiophene):PSS (PEDOT:PSS), in order to form electrically conducting PEMs on fibres and PEM-like structures were formed from polyethylene oxide (PEO) and polyacrylic acid (PAA). In order to study the influence of the PEM on adhesion and paper strength, fibres were treated and used to form sheets which were physically tested according to determine the tensile index and strain at break. Both these systems were studied using different molecular mass fractions. High molecular mass PDADMAC/PSS (&gt;500k/1000k) had a significantly greater influence as a function of the number of layers than low molecular mass PDADMAC/PSS (30k/80k). In contrast, sheets made from high molecular mass PAH/PAA (70k/240k) showed a significantly lower increase in strength than sheets made from low molecular PAH/PAA investigated earlier. Both these systems had a greater influence on paper strength when the cationic polyelectrolyte was adsorbed in the outermost layer. The amount of polyelectrolytes adsorbed on the fibres was determined using polylectrolyte titration (PET) and destructive analytical methods. Adsorption to model surfaces of silicon oxide was studied before the adsorption on fibres, in order to understand the influence on PEM properties of parameters such as salt concentration and adsorption time. Adhesion studies of surfaces coated with PAH/PAA using AFM, showed an increase in adhesion as a function of the number of adsorbed layers. The adhesion was higher when PAH was adsorbed in the outermost layers. Individual fibres were also partly treated using a Dynamic Contact Angle analyser (DCA) and were studied with regard to their wettability. In general, the wettability was lower when the cationic polymer was outermost. The level of adhesion and paper strength are discussed in terms of rigidity and wettability and the PEMs demonstrating a large number of free chain ends, a large chain mobility and a low wettability was found to have the greatest influence to adhesion and paper strength. / QC 20100823

fibre

polyelectorlyte

multilayer

wettability

contact angle

paper strength

atomic force microscopy

surface force apparatus

Cellulose and paper engineering

Cellulosa- och pappersteknik

A study of interactions between an air bubble and a solid surface in a liquid

Wang, Louxiang

Unknown Date

No description available.

Force apparatus

bubble-particle attachment

thin film drainage

film drainage time

induction time

hydrodynamic force

hydrophobicity

force barrier

oil sands

bitumen extraction

Nanorhéologie de fluides complexes aux interfaces / Nanorheology of complex fluids at interfaces

Barraud, Chloé

06 July 2016

Les liquides confinés présentent beaucoup de comportements fascinants, très différents de ceux qui sont observés dans leur volume. Le confinement peut induire un déplacement de l'équilibre des phases (par exemple de la transition liquide-vapeur, aussi appelé condensation capillaire), il peut modifier la température de transition vitreuses des polymères, ou bien imposer un ordre dans l'arrangement moléculaire du fluide. Les modifications des propriétés mécaniques des liquides aux interfaces sont particulièrement importantes au niveau des applications. Cependant au niveau de la compréhension, le simple cas des liquides newtoniens est toujours sujet à controverse, avec d'une part des simulations numériques montrant que la viscosité ne devrait pas être modifiée pour des confinements supérieurs à quelques tailles moléculaires, et d'autre part des expériences non unanimes, montrant parfois des modifications qualitatives des propriétés rhéologiques sous confinement. Récemment nous avons montré que les méthodes d'impédance hydrodynamique en géométrie sphère-plan constituent une méthode privilégiée, non-intrusive et non-ambigüe, pour aborder la nano-mécanique des liquides aux interfaces (1,2). S'agissant d'interphases, cad de couches fluides dont les propriétés sont modifiées par la proximité d'un solide, il est possible d'accéder à leur module sans contact, donc sans la perturbation apportée par une seconde surface. S'agissant de l'effet du confinement sur la rhéologie, nous avons montré que la déformation élastique à l'échelle du pico-mètre des surfaces confinantes, donne une forte modification de la rhéologie apparente du fluide, même en l'absence de tout effet intrinsèque. Le sujet de thèse vise à mettre en oeuvre les méthodes d'impédance hydrodynamique pour étudier la rhéologie de solutions de polymères confinés. On étudiera plus précisément deux systèmes modèles d'importance fondamentale aussi bien que pratique : les brosses de polymères greffés, dont les propriétés mécaniques sont un enjeu dans les applications de lubrification aussi bien que pour les écoulements biologiques, et les solutions de polymères hydro-solubles d'intérêt pour la récupération assistée du pétrole, en vue de comprendre les effets de fluidification sous confinement et de faire la part entre modification de la viscosité et couche de déplétion induite par l'écoulement. Au niveau instrumental, un des enjeux de la thèse sera de mettre en oeuvre les mesures d'impédance hydrodynamique sur deux types d'instruments complémentaires au niveau de l'échelle de la sonde: l'appareil de mesure de forces dynamique (SFA) du Liphy, et l'AFM à détection interférométrique développé à l'Institut Néel. Ces différentes échelles d'investigation devront permettre de préciser les propriétés moyennes mécaniques moyennes des liquides confinés et leurs gradients au voisinage de la paroi. Une perspective du travail sera de mettre en regard les propriétés mécaniques et rhéologiques intrinsèques des brosses polymères déterminées directement sur SFA ou AFM, avec leur propriétés fonctionnelles: propriétés de lubrification des contacts frottants, ou de modification des écoulements des dans micro-canaux. Ceci sera poursuivi sur la plateforme expérimentale mise en place par Lionel Bureau au Liphy : SFA de friction, systèmes micro-fluidiques à visée biomimétique (parois fonctionnalisées par des brosses polymères). L'enjeu sera alors de comprendre comment les propriétés mécaniques et rhéologiques des brosses déterminent celles des systèmes dans lesquels elles interviennent. / Liquids confined present many fascinating behaviors very different from those observed in their volume. Confinement can induce a shift in the balance of phases (eg the liquid-vapor transition, also called capillary condensation), it can change the glass transition temperature of the polymer, or impose order on the molecular arrangement of fluid. The changes in the mechanical properties of liquid interfaces are particularly important in applications. However the level of understanding, the simple case of Newtonian liquids is still controversial, with one hand, numerical simulations show that the viscosity should not be changed for some higher molecular sizes containment, and secondly non-unanimous experiences, sometimes showing qualitative changes in rheological properties under confinement. Recently we have shown that the methods of hydrodynamic impedance sphere-plane geometry is a privileged, non-intrusive method and unambiguous, to discuss the mechanics of nano-liquid interfaces (1,2). As interphase, ie fluid layers whose properties are modified by the proximity of a solid, it is possible to accede their contactless module, so without the disturbance caused by a second surface.S As regards the effect of confinement on the rheology, we have shown that the elastic deformation across the pico meter of confining surfaces, gives a strong modification beyond apparent rheology of the fluid, even in the absence of any intrinsic effect. The thesis aims to implement the hydrodynamic impedance methods to study the rheology of polymer solutions confined. We specifically consider two models of fundamental importance as well as practical systems: brushes grafted polymer whose mechanical properties are an issue in lubrication applications as well as for biological flows and solutions of water-soluble polymers interest in enhanced oil recovery, in order to understand the effects of thinning containment and to distinguish between changes in viscosity and depletion layer induced by the flow. At the instrumental level, one of the challenges of the thesis is to implement the hydrodynamic impedance measurements on two complementary instruments at the level of the probe: the measuring dynamic power (SFA) of Liphy, and AFM interferometric detection developed at the Institut Néel. These different scales of investigation will help to clarify the medium average mechanical properties of liquids confined and their gradients near the wall. A view of work will be to look mechanical and rheological properties of polymer brushes intrinsic determined directly on SFA or AFM with their functional properties: lubricating properties of sliding contacts, or modification of the flow in microchannels. This will continue on the implementation by Lionel Bureau Liphy experimental platform: SFA friction advised biomimetic micro-fluidic systems (walls functionalized polymer brushes). The challenge will be to understand how the mechanical and rheological properties of brushes determine those systems in which they operate.

Nanorhéologie

Fluides complexes

Glissement interfacial

Polyélectrolyte

Appareil à force de surface (SFA)

Élasto-Hydrodynamique

Nano-Rheology

Complex fluids

Interfacial slip

Polyelectrolyte

Surface force apparatus (SFA)

Elasto-Hydrodynamics

530

Paysages énergétique et conformationnel d’interaction de la Synaptotagmin-1 avec des membranes / Energy and conformational landscape of Synaptotagmin-1 interacting with membranes

Gruget, Clémence

11 June 2018

A l’arrivée d’un potentiel d’action au niveau d’une synapse neuronale, des ions calcium (Ca2+) pénètrent dans le neurone, permettant aux protéines SNAREs (N-ethylmaleimide-sensitive factor activating protein receptor) de s’assembler entièrement, engendrant la fusion des vésicules synaptiques contenant les neurotransmetteurs avec la membrane plasmique du neurone. Des protéines régulatrices telles que la Complexine et la Synaptotagmine sont étroitement couplées aux SNAREs et permettent une fusion rapide et synchrone. La Synaptotagmin-1 (Syt1), une protéine transmembranaire localisée sur les vésicules synaptiques, est le senseur calcique de la neurotransmission. Syt1 possède deux domaines de liaison au Ca2+, C2A et C2B, un domaine flexible reliant la région membranaire au C2A, ainsi qu’un court lien entre C2A et C2B. Il a été montré qu’une région polybasique dans le C2B se liait aux lipides anioniques tels que phosphatidylserine (PS) et phosphatidylinositol-4,5-bisphosphate (PIP2) en l’absence de Ca2+. A l’entrée du Ca2+, les ions Ca2+ se lient au C2A et au C2B. La liaison de Syt1 aux ions Ca2+ permet aux résidus non polaires à proximité des sites de liaison au Ca2+ de s’insérer dans la membrane. Si ces mécanismes sont relativement bien acceptés, les mécanismes biochimiques et biophysiques précis du déclenchement de la fusion induit par la liaison de Syt1 au Ca2+ restent flous. Dans ce travail, nous mesurons directement les interactions de Syt1 liée à une membrane avec des membranes anioniques comprenant des lipides PS et PIP2 par un appareil à force de surface (SFA), afin d’imiter la membrane d’une vésicule synaptique contenant Syt1 interagissant avec la membrane plasmique anionique. Nous réalisons une mutagénèse dirigée sur les sites de liaison au Ca2+ de C2A et C2B, ainsi que sur le site polybasique de C2B, pour entièrement cartographier les énergies de liaison à la membrane relatives à ces sites, à la fois en présence et en l’absence d’ions divalents. Nous trouvons que Syt1 se lie avec une énergie de ~6 kBT dans l’EGTA, ~10 kBT dans le Mg2+, et ~18 kBT dans le Ca2+. Des réarrangements moléculaires mesurés pendant le confinement de Syt1 entre les membranes prévalent dans le Ca2+ et dans le Mg2+, et suggèrent que Syt1 se lie initialement via le C2B puis réoriente ses domaines C2 dans la conformation de liaison privilégiée. La neutralisation des sites de liaison au Ca2+ de C2B engendre une réduction radicale de l’énergie de liaison de Syt1 dans le Ca2+, alors que la même mutation dans le C2A a un effet plus nuancé. Ces résultats éclairent sur la coopérativité de C2A et C2B dans leur liaison à la membrane, et montrent un rôle apparent prédominant de C2B. / Upon arrival of an action potential at the neuronal synapse, calcium ions (Ca2+) enter the neuron, allowing soluble N-ethylmaleimide-sensitive factor activating protein receptor (SNARE) proteins to fully zipper, leading to the fusion of pre-docked synaptic vesicles containing neurotransmitters with the plasma membrane of the neurone. Regulatory proteins such as Complexin and Synaptotagmin are closely coupled to SNAREs during synaptic vesicle fusion and lead to synchronous, fast fusion. Synaptotagmin-1 (Syt1) is a transmembrane protein found in synaptic vesicles and is the Ca2+ sensor for synaptic transmission. Syt1 has two Ca2+ binding domains, C2A and C2B, with a flexible linker domain from the membrane region to C2A, and a short linker between C2A and C2B. A polybasic patch in C2B has been shown to bind to anionic lipids such as phophidylserine (PS) and phosphisotinol (PIP2) in the absence of Ca2+. Upon Ca2+ influx, Ca2+ ions bind in C2A and C2B. Ca2+ binding to Syt1 allows non-polar residues nearby the Ca2+ binding sites to insert into the membrane. While these mechanisms are relatively well-accepted, the precise biochemical and biophysical mechanisms for the Syt1 Ca2+ trigger remain unclear. In this work, we directly measure the interactions of Syt1-coated membranes with anionic membranes including PS and PIP2 lipids by the surface forces apparatus (SFA) technique, in order to mimic a Syt1-coated synaptic vesicle membrane interacting with the anionic plasma membrane. We perform site directed mutagenesis of the Ca2+ binding sites of C2A and C2B, along with the polybasic patch in C2B, to fully map the site-binding energetics of Syt1 with membranes, both in the absence and presence of divalent ions. We find that Syt1 binds with ~6 kBT in EGTA, ~10 kBT in Mg2+, and ~18 kBT in Ca2+. Molecular rearrangements measured during confinement of Syt1 between membranes are more prevalent in Ca2+ and Mg2+ and suggest that Syt1 initially binds through C2B, then reorients the C2 domains into the preferred binding configuration. Neutralization of C2B Ca2+ binding site leads to a drastic decrease of Syt1 binding energy in Ca2+, while the same mutation in C2A has a milder effect. These results illuminate that C2A and C2B cooperate in membrane binding, with an apparent predominant role of C2B.

Synaptotagmine

Appareil à force de surface

Mutagénèse dirigée

Synaptotagmin

Surface force apparatus

Proteinmembrane interaction measurements

Directed mutagenesis

571.4

616.8

Caractérisation et utilisation de polymères en brosse pour la lubrification des tissus et des dispositifs médicaux

Pham, Duy Anh

08 1900

La friction entre les surfaces mobiles de l’organisme peut être un problème difficile à résoudre, notamment dans les pathologies dégénératives comme l’arthrose ou la sécheresse oculaire. Malgré le développement de nombreux produits pharmaceutiques, les matériaux actuellement utilisés pour protéger les tissus blessés et les dispositifs biomédicaux contre l'usure par frottement sont encore limités dans leurs performances. Il existe un besoin urgent de matériaux injectables capables de protéger ces tissus et dispositifs afin de prolonger leur durée de vie et de traiter efficacement des maladies dégénératives. Parmi les innovations de la dernière décennie, les polymères à structure dite « en brosse » (BBs) se sont révélés prometteurs pour amoindrir les problèmes de friction et d'usure. Inspirés de l’architecture spécifique du protéoglycane 4, l'un des principaux composants lubrifiants du cartilage, les macromolécules BBs sont constituées d’un squelette linéaire et de chaînes latérales formant une brosse dense pouvant maintenir de l’eau sous une pression élevée. Les différentes structures des BBs, selon le squelette et leurs chaînes latérales, conduisent à plusieurs caractéristiques morphologiques et propriétés tribologiques intéressantes dans l’ingénierie tissulaire. Bien que leurs propriétés lubrifiantes aient été prouvées dans plusieurs études, les BBs n’ont à ce jour que peu d’applications. D’une part, la corrélation entre leur structure et leurs propriétés physicochimiques n’est pas encore clairement établie. D’autre part, il manque encore des études relatives à l’efficacité des BBs sur de vrais tissus. Pour pallier ce problème, notre projet vise à caractériser les propriétés physicochimiques et tribologiques des BBs sur différents types de surfaces en fonction de leur structure. La longueur du squelette, la densité de greffage et l’addition du groupe d’ancrage sont les 3 variables principales étudiées dans ce projet. La lubrification ainsi que d’autres propriétés importantes des BBs ont été évaluées sur les surfaces molles des cartilages, des yeux et des lentilles en contact. Les tests tribologiques ont été menés en utilisant un appareil à force de surface (SFA) via l’association du protocole classique et avancé qui l’adapte aux surfaces testées. A côté de la tribologie, l’affinité cinétique, la toxicité, les propriétés antisalissure et anti-inflammatoire des BBs sur les interfaces ont aussi été étudiées dans ce projet via les techniques de LigandTracer et de microscope fluorescent. / Friction between the body's moving surfaces can be a difficult problem to solve, particularly in degenerative pathologies such as osteoarthritis or dry eye. Despite the development of numerous pharmaceutical products, the materials currently used to protect injured tissues and biomedical devices against frictional wear are still limited in their performance. There is an urgent need for injectable materials capable of protecting these tissues and devices in order to extend their life and effectively treat degenerative diseases. Among the innovations of the last decade, polymers with a so-called "brush structure" (BBs) have shown promise in reducing friction and wear problems. Inspired by the specific architecture of proteoglycan 4, one of the main lubricating components of cartilage, BBs macromolecules consist of a linear backbone and side chains forming a dense brush capable of holding water under high pressure. The different structures of BBs, depending on the backbone and their side chains, lead to several morphological features and tribological properties of interest in tissue engineering. Although their lubricating properties have been proven in several studies, BBs have few applications to date. On the one hand, the correlation between their structure and physicochemical properties has not yet been clearly established. On the other hand, studies on the effectiveness of BBs on real tissues are still lacking. To overcome this problem, our project aims to characterize the physicochemical and tribological properties of BBs on different types of surfaces, depending on their structure. Backbone length, graft density and anchoring group are the 3 main variables studied in this project. Lubrication and other important properties of BBs were evaluated on the soft surfaces of cartilages, eyes and contact lenses. Tribological testing was carried out using a Surface Force Apparatus (SFA) via a combination of the classic and advanced protocol, adapting it to the surfaces tested. Alongside tribology, the kinetic affinity, toxicity, anti-fouling and anti-inflammatory properties of BBs on interfaces were also studied in this project via LigandTracer and fluorescent microscopy techniques.

Lubrification

Lubrication

Friction

Polymère en brosse

Bottlebrush polymer

Bio-affinité

Bio-affinity

Appareil à force de surface

Surface force apparatus