The role of chemistry and strut porosity and the influence of serum proteins in modulating cellular response to bone graft substitutes

Castagna, Viviana

January 2015

The objective of this thesis was to investigate the role of hydroxyapatite and silicate-substituted hydroxyapatite synthetic bone graft substitute (SBG) material properties in modulating the processes of protein adsorption and desorption, and their combined role in the subsequent regulation of cell attachment, proliferation and differentiation on the surfaces of these materials in vitro. As a result of their purported role in promoting osteogenic behaviour in vivo the materials parameters selected for investigation were chemistry (stoichiometric hydroxyapatite (HA) versus 0.8wt% silicate-substituted hydroxyapatite (SA)) and strut porosity (20% versus 30% strut porosity). Cell attachment and response to different SBG was assessed to samples in the ‘as received’ condition as well as after a series of sequentially varied pre-treatments with solutions of phosphate buffered saline or cell culture media either unsupplemented or in combination with mixed serum proteins and/or Fibronectin (Fn). This enabled investigation of the effect of sample chemistry and strut porosity on mixed serum protein interactions and Fn adsorption under both competitive and non-competitive conditions, and the study of subsequent regulation of cell attachment and response as a consequence of pre-treatment. Results showed that serum protein interactions were key to modulation of cell response to chemistry, and there was evidence that for Fn this may be related to conformational changes in the adsorbed protein rather than its level of enrichment in the protein interlayer. In terms of the materials properties investigated strut porosity was found to be the most dominant factor in the regulation of cell response, where SBG with 30% strut porosity promoted human mesenchymal stem cell (hMSC) osteoblastic differentiation. Moreover hMSC response to SBG with 30% strut porosity seemed to be less sensitive to pre-treatment. In conclusion, the results of these experiments indicate that strut porosity more directly influences the cellular response to HA and SA BGS than chemistry in vitro. Moreover, the role that Fn and other serum proteins have in regulating this response is dependent on the physiological environment and BGS chemistry.

612

Engineered Surfaces for Biomaterials and Tissue Engineering

Peter George

Unknown Date

The interaction of materials with biological systems is of critical importance to a vast number of applications from medical implants, tissue engineering scaffolds, blood-contacting devices, cell-culture products, as well as many other products in industries as diverse as agriculture. This thesis describes a method for the modification of biomaterial surfaces and the generation of tissue engineering scaffolds that utilises the self assembly of poly (styrene)-block-poly (ethylene oxide) (PS-PEO) block copolymers. Block copolymers consist of alternating segments of two or more chemically distinct polymers. The salient feature of these materials is their ability to self organise into a wide range of micro-phase separated structures generating patterned surfaces that have domain sizes in the order of 10-100nm. Further, it is also possible to specifically functionalise only one segment of the block copolymer, providing a means to precisely locate specific biological signals within the 10-100nm domains of a nano-patterned surface, formed via the programmed micro-phase separation of the block copolymer system. The density and spatial location of signalling molecules can be controlled by altering several variables, such as block length, block asymmetry, as well as processing parameters, providing the potential to authentically emulate the cellular micro to nano-environment and thus greatly improving on existing biomaterial and tissue engineering technologies. This thesis achieved several aims as outlined below; Developed methods to control the self-assembly of PS-PEO block copolymers and generate nano-patterned surfaces and scaffolds with utility for biomaterials applications. PS-PEO diblock copolymers were blended with polystyrene (PS) homopolymer and spin cast, resulting in the rapid self-assembly of vertically oriented PEO cylinders in a matrix of PS. Due to the kinetically constrained phase-separation of the system, increasing addition of homopolymer is shown to reduce the diameter of the PEO domains. This outcome provides a simple method that requires the adjustment of a single variable to tune the size of vertically oriented PEO domains between 10-100nm. Polymeric scaffolds for tissue engineering were manufactured via a method that combines macro-scale temperature induced phase separation with micro-phase separation of block copolymers. The phase behaviour of these polymer-solvent systems is described, and potential mechanisms leading to this spectacular structure formation are presented. The result is highly porous scaffolds with surfaces comprised of nano-scale self-assembled block copolymer domains, representing a significant advance in currently available technologies. Characterised the properties of these unique nano-structured materials as well as their interaction with proteinaceous fluids and cells. Nano-patterned PS-PEO self-assembled surfaces showed a significant reduction in protein adsorption compared to control PS surfaces. The adhesion of NIH 3T3 fibroblast cells was shown to be significantly affected by the surface coverage of PEO nano-domains formed by copolymer self-assembly. These nano-islands, when presented at high number density (almost 1000 domains per square micron), were shown to completely prevent cellular attachment, even though small amounts of protein were able to bind to the surface. In order to understand the mechanism by which these surfaces resisted protein and cellular adsorption we utilised neutron reflection to study their solvation and swelling properties. The results indicate that the PEO domains are highly solvated in water; however, the PEO chains do not extend into the solvent but remain in their isolated domains. The data supports growing evidence that the key mechanism by which PEO prevents protein adsorption is the blocking of protein adsorption sites. Control the nano-scale presentation of cellular adhesion and other biological molecules via the self-assembly of functionalised PS-PEO block copolymers Precise control over the nano-scale presentation of adhesion molecules and other biological factors represents a new frontier for biomaterials science. Recently, the control of integrin spacing and cellular shape has been shown to affect fundamental biological processes, including differentiation and apoptosis. We present the self-assembly of maleimide functionalised PS-PEO copolymers as a simple, yet highly precise method for controlling the position of cellular adhesion molecules. By controlling the phase separation of the functional PS-PEO block copolymer we alter the nano-scale (on PEO islands of 8-14 nm in size) presentation of the adhesion peptide, GRGDS, decreasing lateral spacing from 62 nm to 44 nm and increasing the number density from ~ 450 to ~ 900 islands per um2. The results indicate that the spreading of NIH-3T3 fibroblasts increases as the spacing between islands of RGD binding peptides decreases. Further, the same functional PS-PEO surfaces were utilised to immobilise poly-histidine tagged proteins and ECM fragments. The technologies developed in this thesis aim to improve on several weaknesses of existing biomaterials, in particular, directing cellular behaviour on surfaces, and within tissue engineering scaffolds, but also, on the prevention of fouling of biomaterials via non-specific protein adsorption. The application of block copolymer self-assembly for biomaterial and tissue engineering systems described in this thesis has great potential as a platform technology for the investigation of fundamental cell-surface and protein-surface interactions as well as for use in existing and emerging biomedical applications.

Block copolymer

polystyrene-block-poly (ethylene oxide)

self-assembly

Nanotechnolgy

Surface Modification

Protein Adsorption

cell spreading

tissue engineering

integrin

RGD

Characterization and optimization of the in vitro motility assay for fundamental studies of myosin II

Persson, Malin

January 2013

Myosin II is the molecular motor responsible for muscle contraction. It transforms the chemical energy in ATP into mechanical work while interacting with actin filaments in so called cross-bridge cycles. Myosin II or its proteolytic fragments e.g., heavy meromyosin (HMM) can be adsorbed to moderately hydrophobic surfaces in vitro, while maintaining their ability to translocate actin filaments. This enables observation of myosin-induced actin filament sliding in a microscope. This “in vitro motility assay” (IVMA) is readily used in fundamental studies of actomyosin, including studies of muscle contraction. The degree of correlation of the myosin II function in the IVMA with its function in muscle depends on how the myosin molecules are arranged on the surface. Therefore a multi-technique approach, including total internal reflection spectroscopy, fluorescence interference contrast microscopy and quartz crystal microbalance with dissipation, was applied to characterize the HMM surface configurations. Several configurations with varying distributions were identified depending on the surface property. The most favorable HMM configurations for actin binding were observed on moderately hydrophobic surfaces.   The effects on actomyosin function of different cargo sizes and amount of cargo loaded on an actin filament were also investigated. No difference in sliding velocities could be observed, independent of cargo size indicating that diffusional processive runs of myosin II along an actin filament are not crucial for actomyosin function in muscle. Furthermore, a tool for accurate velocity measurements appropriate for IVMAs at low [MgATP] was developed by utilizing the actin filament capping protein CapZ. These improvements allowed an investigation of the [MgATP]-velocity relationship to study possible processivity in fast skeletal muscle myosin II.  It is shown that the [MgATP]–velocity relationship is well described by a Michaelis-Menten hyperbola.  In addition, statistical cross-bridge modeling showed that the experimental results are in good agreement with recent findings of actomyosin cross-bridge properties, e.g., non-linear cross-bridge elasticity. However, no effect of inter-head cooperativity could be observed.   In conclusion, the described results have contributed to in-depth understanding of the actomyosin cross-bridge cycle in muscle contraction.

Myosin II

skeletal muscle

actomyosin

in vitro motility assay

protein adsorption

cargo transportation

CapZ

cross-bridge cycle

inter-head cooperativity

processivity

Engineered Surfaces for Biomaterials and Tissue Engineering

Peter George

Unknown Date

The interaction of materials with biological systems is of critical importance to a vast number of applications from medical implants, tissue engineering scaffolds, blood-contacting devices, cell-culture products, as well as many other products in industries as diverse as agriculture. This thesis describes a method for the modification of biomaterial surfaces and the generation of tissue engineering scaffolds that utilises the self assembly of poly (styrene)-block-poly (ethylene oxide) (PS-PEO) block copolymers. Block copolymers consist of alternating segments of two or more chemically distinct polymers. The salient feature of these materials is their ability to self organise into a wide range of micro-phase separated structures generating patterned surfaces that have domain sizes in the order of 10-100nm. Further, it is also possible to specifically functionalise only one segment of the block copolymer, providing a means to precisely locate specific biological signals within the 10-100nm domains of a nano-patterned surface, formed via the programmed micro-phase separation of the block copolymer system. The density and spatial location of signalling molecules can be controlled by altering several variables, such as block length, block asymmetry, as well as processing parameters, providing the potential to authentically emulate the cellular micro to nano-environment and thus greatly improving on existing biomaterial and tissue engineering technologies. This thesis achieved several aims as outlined below; Developed methods to control the self-assembly of PS-PEO block copolymers and generate nano-patterned surfaces and scaffolds with utility for biomaterials applications. PS-PEO diblock copolymers were blended with polystyrene (PS) homopolymer and spin cast, resulting in the rapid self-assembly of vertically oriented PEO cylinders in a matrix of PS. Due to the kinetically constrained phase-separation of the system, increasing addition of homopolymer is shown to reduce the diameter of the PEO domains. This outcome provides a simple method that requires the adjustment of a single variable to tune the size of vertically oriented PEO domains between 10-100nm. Polymeric scaffolds for tissue engineering were manufactured via a method that combines macro-scale temperature induced phase separation with micro-phase separation of block copolymers. The phase behaviour of these polymer-solvent systems is described, and potential mechanisms leading to this spectacular structure formation are presented. The result is highly porous scaffolds with surfaces comprised of nano-scale self-assembled block copolymer domains, representing a significant advance in currently available technologies. Characterised the properties of these unique nano-structured materials as well as their interaction with proteinaceous fluids and cells. Nano-patterned PS-PEO self-assembled surfaces showed a significant reduction in protein adsorption compared to control PS surfaces. The adhesion of NIH 3T3 fibroblast cells was shown to be significantly affected by the surface coverage of PEO nano-domains formed by copolymer self-assembly. These nano-islands, when presented at high number density (almost 1000 domains per square micron), were shown to completely prevent cellular attachment, even though small amounts of protein were able to bind to the surface. In order to understand the mechanism by which these surfaces resisted protein and cellular adsorption we utilised neutron reflection to study their solvation and swelling properties. The results indicate that the PEO domains are highly solvated in water; however, the PEO chains do not extend into the solvent but remain in their isolated domains. The data supports growing evidence that the key mechanism by which PEO prevents protein adsorption is the blocking of protein adsorption sites. Control the nano-scale presentation of cellular adhesion and other biological molecules via the self-assembly of functionalised PS-PEO block copolymers Precise control over the nano-scale presentation of adhesion molecules and other biological factors represents a new frontier for biomaterials science. Recently, the control of integrin spacing and cellular shape has been shown to affect fundamental biological processes, including differentiation and apoptosis. We present the self-assembly of maleimide functionalised PS-PEO copolymers as a simple, yet highly precise method for controlling the position of cellular adhesion molecules. By controlling the phase separation of the functional PS-PEO block copolymer we alter the nano-scale (on PEO islands of 8-14 nm in size) presentation of the adhesion peptide, GRGDS, decreasing lateral spacing from 62 nm to 44 nm and increasing the number density from ~ 450 to ~ 900 islands per um2. The results indicate that the spreading of NIH-3T3 fibroblasts increases as the spacing between islands of RGD binding peptides decreases. Further, the same functional PS-PEO surfaces were utilised to immobilise poly-histidine tagged proteins and ECM fragments. The technologies developed in this thesis aim to improve on several weaknesses of existing biomaterials, in particular, directing cellular behaviour on surfaces, and within tissue engineering scaffolds, but also, on the prevention of fouling of biomaterials via non-specific protein adsorption. The application of block copolymer self-assembly for biomaterial and tissue engineering systems described in this thesis has great potential as a platform technology for the investigation of fundamental cell-surface and protein-surface interactions as well as for use in existing and emerging biomedical applications.

Block copolymer

polystyrene-block-poly (ethylene oxide)

self-assembly

Nanotechnolgy

Surface Modification

Protein Adsorption

cell spreading

tissue engineering

integrin

RGD

Engineered Surfaces for Biomaterials and Tissue Engineering

Peter George

Unknown Date

The interaction of materials with biological systems is of critical importance to a vast number of applications from medical implants, tissue engineering scaffolds, blood-contacting devices, cell-culture products, as well as many other products in industries as diverse as agriculture. This thesis describes a method for the modification of biomaterial surfaces and the generation of tissue engineering scaffolds that utilises the self assembly of poly (styrene)-block-poly (ethylene oxide) (PS-PEO) block copolymers. Block copolymers consist of alternating segments of two or more chemically distinct polymers. The salient feature of these materials is their ability to self organise into a wide range of micro-phase separated structures generating patterned surfaces that have domain sizes in the order of 10-100nm. Further, it is also possible to specifically functionalise only one segment of the block copolymer, providing a means to precisely locate specific biological signals within the 10-100nm domains of a nano-patterned surface, formed via the programmed micro-phase separation of the block copolymer system. The density and spatial location of signalling molecules can be controlled by altering several variables, such as block length, block asymmetry, as well as processing parameters, providing the potential to authentically emulate the cellular micro to nano-environment and thus greatly improving on existing biomaterial and tissue engineering technologies. This thesis achieved several aims as outlined below; Developed methods to control the self-assembly of PS-PEO block copolymers and generate nano-patterned surfaces and scaffolds with utility for biomaterials applications. PS-PEO diblock copolymers were blended with polystyrene (PS) homopolymer and spin cast, resulting in the rapid self-assembly of vertically oriented PEO cylinders in a matrix of PS. Due to the kinetically constrained phase-separation of the system, increasing addition of homopolymer is shown to reduce the diameter of the PEO domains. This outcome provides a simple method that requires the adjustment of a single variable to tune the size of vertically oriented PEO domains between 10-100nm. Polymeric scaffolds for tissue engineering were manufactured via a method that combines macro-scale temperature induced phase separation with micro-phase separation of block copolymers. The phase behaviour of these polymer-solvent systems is described, and potential mechanisms leading to this spectacular structure formation are presented. The result is highly porous scaffolds with surfaces comprised of nano-scale self-assembled block copolymer domains, representing a significant advance in currently available technologies. Characterised the properties of these unique nano-structured materials as well as their interaction with proteinaceous fluids and cells. Nano-patterned PS-PEO self-assembled surfaces showed a significant reduction in protein adsorption compared to control PS surfaces. The adhesion of NIH 3T3 fibroblast cells was shown to be significantly affected by the surface coverage of PEO nano-domains formed by copolymer self-assembly. These nano-islands, when presented at high number density (almost 1000 domains per square micron), were shown to completely prevent cellular attachment, even though small amounts of protein were able to bind to the surface. In order to understand the mechanism by which these surfaces resisted protein and cellular adsorption we utilised neutron reflection to study their solvation and swelling properties. The results indicate that the PEO domains are highly solvated in water; however, the PEO chains do not extend into the solvent but remain in their isolated domains. The data supports growing evidence that the key mechanism by which PEO prevents protein adsorption is the blocking of protein adsorption sites. Control the nano-scale presentation of cellular adhesion and other biological molecules via the self-assembly of functionalised PS-PEO block copolymers Precise control over the nano-scale presentation of adhesion molecules and other biological factors represents a new frontier for biomaterials science. Recently, the control of integrin spacing and cellular shape has been shown to affect fundamental biological processes, including differentiation and apoptosis. We present the self-assembly of maleimide functionalised PS-PEO copolymers as a simple, yet highly precise method for controlling the position of cellular adhesion molecules. By controlling the phase separation of the functional PS-PEO block copolymer we alter the nano-scale (on PEO islands of 8-14 nm in size) presentation of the adhesion peptide, GRGDS, decreasing lateral spacing from 62 nm to 44 nm and increasing the number density from ~ 450 to ~ 900 islands per um2. The results indicate that the spreading of NIH-3T3 fibroblasts increases as the spacing between islands of RGD binding peptides decreases. Further, the same functional PS-PEO surfaces were utilised to immobilise poly-histidine tagged proteins and ECM fragments. The technologies developed in this thesis aim to improve on several weaknesses of existing biomaterials, in particular, directing cellular behaviour on surfaces, and within tissue engineering scaffolds, but also, on the prevention of fouling of biomaterials via non-specific protein adsorption. The application of block copolymer self-assembly for biomaterial and tissue engineering systems described in this thesis has great potential as a platform technology for the investigation of fundamental cell-surface and protein-surface interactions as well as for use in existing and emerging biomedical applications.

Block copolymer

polystyrene-block-poly (ethylene oxide)

self-assembly

Nanotechnolgy

Surface Modification

Protein Adsorption

cell spreading

tissue engineering

integrin

RGD

Engineered Surfaces for Biomaterials and Tissue Engineering

Peter George

Unknown Date

The interaction of materials with biological systems is of critical importance to a vast number of applications from medical implants, tissue engineering scaffolds, blood-contacting devices, cell-culture products, as well as many other products in industries as diverse as agriculture. This thesis describes a method for the modification of biomaterial surfaces and the generation of tissue engineering scaffolds that utilises the self assembly of poly (styrene)-block-poly (ethylene oxide) (PS-PEO) block copolymers. Block copolymers consist of alternating segments of two or more chemically distinct polymers. The salient feature of these materials is their ability to self organise into a wide range of micro-phase separated structures generating patterned surfaces that have domain sizes in the order of 10-100nm. Further, it is also possible to specifically functionalise only one segment of the block copolymer, providing a means to precisely locate specific biological signals within the 10-100nm domains of a nano-patterned surface, formed via the programmed micro-phase separation of the block copolymer system. The density and spatial location of signalling molecules can be controlled by altering several variables, such as block length, block asymmetry, as well as processing parameters, providing the potential to authentically emulate the cellular micro to nano-environment and thus greatly improving on existing biomaterial and tissue engineering technologies. This thesis achieved several aims as outlined below; Developed methods to control the self-assembly of PS-PEO block copolymers and generate nano-patterned surfaces and scaffolds with utility for biomaterials applications. PS-PEO diblock copolymers were blended with polystyrene (PS) homopolymer and spin cast, resulting in the rapid self-assembly of vertically oriented PEO cylinders in a matrix of PS. Due to the kinetically constrained phase-separation of the system, increasing addition of homopolymer is shown to reduce the diameter of the PEO domains. This outcome provides a simple method that requires the adjustment of a single variable to tune the size of vertically oriented PEO domains between 10-100nm. Polymeric scaffolds for tissue engineering were manufactured via a method that combines macro-scale temperature induced phase separation with micro-phase separation of block copolymers. The phase behaviour of these polymer-solvent systems is described, and potential mechanisms leading to this spectacular structure formation are presented. The result is highly porous scaffolds with surfaces comprised of nano-scale self-assembled block copolymer domains, representing a significant advance in currently available technologies. Characterised the properties of these unique nano-structured materials as well as their interaction with proteinaceous fluids and cells. Nano-patterned PS-PEO self-assembled surfaces showed a significant reduction in protein adsorption compared to control PS surfaces. The adhesion of NIH 3T3 fibroblast cells was shown to be significantly affected by the surface coverage of PEO nano-domains formed by copolymer self-assembly. These nano-islands, when presented at high number density (almost 1000 domains per square micron), were shown to completely prevent cellular attachment, even though small amounts of protein were able to bind to the surface. In order to understand the mechanism by which these surfaces resisted protein and cellular adsorption we utilised neutron reflection to study their solvation and swelling properties. The results indicate that the PEO domains are highly solvated in water; however, the PEO chains do not extend into the solvent but remain in their isolated domains. The data supports growing evidence that the key mechanism by which PEO prevents protein adsorption is the blocking of protein adsorption sites. Control the nano-scale presentation of cellular adhesion and other biological molecules via the self-assembly of functionalised PS-PEO block copolymers Precise control over the nano-scale presentation of adhesion molecules and other biological factors represents a new frontier for biomaterials science. Recently, the control of integrin spacing and cellular shape has been shown to affect fundamental biological processes, including differentiation and apoptosis. We present the self-assembly of maleimide functionalised PS-PEO copolymers as a simple, yet highly precise method for controlling the position of cellular adhesion molecules. By controlling the phase separation of the functional PS-PEO block copolymer we alter the nano-scale (on PEO islands of 8-14 nm in size) presentation of the adhesion peptide, GRGDS, decreasing lateral spacing from 62 nm to 44 nm and increasing the number density from ~ 450 to ~ 900 islands per um2. The results indicate that the spreading of NIH-3T3 fibroblasts increases as the spacing between islands of RGD binding peptides decreases. Further, the same functional PS-PEO surfaces were utilised to immobilise poly-histidine tagged proteins and ECM fragments. The technologies developed in this thesis aim to improve on several weaknesses of existing biomaterials, in particular, directing cellular behaviour on surfaces, and within tissue engineering scaffolds, but also, on the prevention of fouling of biomaterials via non-specific protein adsorption. The application of block copolymer self-assembly for biomaterial and tissue engineering systems described in this thesis has great potential as a platform technology for the investigation of fundamental cell-surface and protein-surface interactions as well as for use in existing and emerging biomedical applications.

Block copolymer

polystyrene-block-poly (ethylene oxide)

self-assembly

Nanotechnolgy

Surface Modification

Protein Adsorption

cell spreading

tissue engineering

integrin

RGD

Příprava tenkých vrstev plazmovou polymerací jako stabilních podložek pro biolékařské aplikace / Thin films of plasma polymers as stable supports for biomedical applications

Gordeev, Ivan

January 2012

Title: Thin films of plasma polymers as stable supports for biomedical applications Author: Ivan Gordeev Institute: Charles University in Prague, Department of Macromolecular Physics Supervisor of the doctoral thesis: Doc. Ing. Andrey Shukurov, Ph.D, Charles University in Prague, Department of Macromolecular Physics. Abstract: Plasma polymers have been widely considered for use as bio-active coatings. In biomedicine, the surfaces that withstand accumulation of biofilms are of particular importance. This thesis is focused on development of new plasma-based methods for deposition of bio-resistant (non-fouling) plasma polymers. Poly(ethylene oxide) was the subject material. R.f. magnetron sputtering, plasma-assisted thermal vapour deposition and amplitude modulated atmospheric pressure surface dielectric barrier discharge were the methods adapted to fabricate thin films with tunable chemical composition, cross-link density and biological response. A new insight was gained into the processes of plasma polymerization as well as into composition/structure relationship and its effect on biological properties of resultant films. Keywords: plasma polymerization, PEO, 'non-fouling' properties, protein adsorption, cell adhesion

Medium sized molecules clearance through artificial kidneys / Clairance de molécules de taille moyenne à travers un rein artificiel

Snisarenko, Dmytro

07 November 2016

Malgré une longue histoire de développement, l'hémodialyse (rein artificiel) possède encore quelques limitations, telles que la perte des propriétés initiales de la membrane en cours de traitement à cause du colmatage et la mauvaise élimination des toxines urémiques de taille moyenne. La présente étude fait partie d'un projet européen nommé BioArt dont le but est d'apporter des solutions à ces limites. Dans cet objectif, l'un des partenaires du projet a proposé le développement d'un nouveau concept de membrane double couche au sein de laquelle sont incorporées des particules adsorbantes. Une caractérisation complète de cette nouvelle membrane était alors nécessaire, plus précisément l'impact de la matrice mixte sur l'élimination des toxines urémiques de divers groupes devait être évalué, ainsi que la propension du matériau membranaire à se colmater. Les études des phénomènes de colmatage sont classiquement menées à l'échelle macroscopique (faisceau de fibres creuses) sans analyse à l'échelle d'une fibre isolée. Le but premier de la présente thèse a alors été de proposer un dispositif permettant une étude du colmatage membranaire induit par la protéine à l'échelle microscopique. Un dispositif microfluidique transparent dans lequel la membrane polymère est insérée a été élaboré et mis en œuvre pour la filtration des protéines modèles : l'albumine de sérum bovin (BSA) et l'a-lactalbumine. Grâce au couplage avec la microscopie de fluorescence, différents modes d'adsorption des protéines sur la surface de la membrane ont été observés et liés aux variations des conditions hydrodynamiques à l'intérieur de la puce. Il a été constaté, sous certaines conditions, une différence dans l'accumulation de protéines entre l'entrée, le centre et la sortie du canal tandis que dans d'autres conditions cet effet s'annule. En outre, un phénomène inattendu, l'agrégation de l'a-lactalbumine, a été observé au cours de la filtration. La localisation dans le canal et la forme des agrégats dépendent également des conditions hydrodynamiques et de la pression transmembranaire appliquée. Dans le but d'optimiser la conception de la membrane vis à vis de son aptitude à éliminer des molécules de taille moyenne de la circulation sanguine, un modèle mathématique a été proposé. L'objectif du modèle était, en prenant en compte la présence de particules adsorbantes à l'intérieur de la membrane double couche, de rendre compte de la combinaison des trois mécanismes d'élimination du soluté : la convection, la diffusion et l'adsorption. Le modèle permet de prédire l'influence de divers paramètres tels que la diffusivité de la molécule, l'épaisseur de la membrane, la présence de la convection, la charge en particules adsorbantes, sur l'intensification des flux à travers la membrane. Le modèle semble être un outil utile pouvant être appliqué à l'optimisation de membranes pour l'élimination des toxines. / Despite a long history of development, the hemodialysis procedure (artificial kidney) still possesses some limitations, such as loss of the initial properties of the membrane due to fouling and poor removal of the middle sized uremic toxins. The present study is part of an European project named BioArt the aim of which was to overcome these limitations. In that objective, one of the partners of BioArt project reported on the development of the novel promising concept of double layer membrane with embedded adsorptive particles. A thorough characterization of the new membrane was then necessary, more precisely the extent to which mixed matrix layer can improve the removal of the uremic toxins from various groups needed to be evaluated, as well as the propensity of the membrane material to become fouled. The studies of the fouling phenomena are conventionally performed at the macro scale (bundle of hollow fibers) without insights of what is happening at the scale of an isolated fiber. Therefore, the primary aim of the present Thesis was to transfer the research of the protein-induced membrane fouling from the macro to the micro scale. A novel transparent microfluidics device with the polymeric membrane inside has been developed and applied for the filtration of model proteins: bovine serum albumin (BSA) and a-lactalbumin. Thanks to the coupling of the microchip with the fluorescent microscopy, different patterns of protein deposition on the membrane surface were observed and related to the variations in the hydrodynamic conditions inside the microchip. It was found that at certain conditions one may observe the difference in protein accumulation in the inlet, the middle, and the outlet of the channel while at other conditions this effect vanishes. Additionally, the unexpected phenomena of a-lactalbumin aggregation was observed over the course of filtration. The location and shape of the aggregates were also dependent on the hydrodynamic conditions and the applied transmembrane pressure. Aiming to address the problem of membrane design optimization for the enhancement of the middle molecules elimination from the bloodstream, a mathematical model, which accounts for the presence of adsorptive particles inside the complex double-layer membrane, has been proposed. The objective of the model was to understand the interplay of three solute removal mechanisms: convection, diffusion, and adsorption. The model allows predicting the influence of various parameters such as molecule diffusivity, membrane thickness, the presence of convection, content of adsorptive particles on the flux intensification across the membrane. The developed model seems to be a useful tool, which may be applied to design optimized membranes for the removal of toxins.

Hémodialyse

Dispositif microfluidique

Colmatage de la membrane

Adsorption de la protéine

Modèle de transfert de la masse

Hemodialysis

Microfluidics device

Membrane fouling

Protein adsorption

Mass transfer model

Design of multi-stimuli responsive films through layer-by-layer assembly for the control of protein adsorption / Conception de films sensibles multi-stimuli assemblage couche-par-couche pour le contrôle d'adsorption de protéine

Osypova, Alina

16 October 2015

L'adsorption de protéine sur une surface artificielle solide est un phénomène fondamental qui détermine la réponse biologique d'un organisme vivant entrant dans n'importe quel matériel d'implant. Donc, l'adaptation de surfaces pour l'adsorption de protéine contrôlée est au coeur de beaucoup de champs de recherche d'aujourd'hui incluant la science de matériels et la biotechnologie. Dans ce contexte, les matériels sensibles de stimulus qui peuvent changer leurs propriétés comme une réponse à une petite monnaie dans leur environnement physicochimique attirent un grand intérêt comme ils permettent la création de surfaces avec des propriétés commutables pour le contrôle d'adsorption de protéine. Dans cette thèse, nous faisons un rapport sur la conception et l'élaboration de films minces sensibles de stimulus multi et de nanotubes. À cette fin, nous avons employé la couche-par-couche robuste et polyvalente… / Protein adsorption on a solid artificial surface is a fundamental phenomenon that determines the biological response of a living organism entering any implant material. Therefore, tailoring surfaces for controlled protein adsorption is at the heart of many of today's research fields including biotechnology and materials science. In this context, stimuli-responsive materials that are able to change their properties as a response to a small change in their physico-chemical environment are attracting a great interest as they allow the creation of surfaces with switchable properties for the control of protein adsorption. In this thesis, we report on the design and elaboration of multi stimuli-responsive thin films and nanotubes. For this purpose, we employed the robust and versatile layer-by-layer (LbL) assembly technique to incorporate block copolymers made of poly(acrylic acid) PAA and poly(N-isopropylacrylamide) PNIPAM with tunable and well-controlled block lengths. The combination of ellipsometry, quartz crystal microbalance with dissipation monitoring (QCM-D), surface plasmon resonance (SPR) and infrared data reveal the possibility to build up (PAH/PAA-b-PNIPAM)n multilayers. The stimuli-responsive properties of these LbL films were examined by monitoring the adsorption of proteins by means of QCM-D and fluorescence measurements, while varying (i) temperature, (ii) pH, (iii) ionic strength, or (iv) a combination of the above parameters. It appears that all these stimuli strongly influence the amount of adsorbed proteins. In short, these new PNIPAM block copolymer-based LbL coatings are easy to build on substrates of various nature and geometry (including nanoporous membranes).

Block-Copolymer

L'adsorption de proteine

Thermosensibles

Couche par couche

Auto-Assemblage

L'adsorption à la surface

Protein adsorption

Layer-by-layer

Block-copolymer

541.3

The physics of pregnancy tests : a biophysical study of interfacial protein adsorption

Cowsill, Benjamin James

January 2012

Pregnancy tests and related immunoassays are heavily dependent on specific and non-specific protein adsorption. These interfacial processes are affected by many factors that influence the in situ conformations of interfacially immobilised antibodies. This thesis examines a number of representative features with dual polarisation interferometry (DPI) and neutron reflection (NR), thus combining real-time dynamic monitoring with high interfacial structural resolution. Bovine serum albumin (BSA) was initially used as a model system to compare the surface coverage and thickness measurements of DPI and NR. The results show that DPI and NR provided similar surface coverage data but the measured thicknesses differed at BSA concentrations above 0.1 mg/ml. This discrepancy arose from the adoption of the uniform-layer model used by DPI for data analysis and the greater thickness sensitivity of NR. A model pregnancy immunoassay was built in steps on a silica surface so that the adsorption of each protein could be accurately monitored. Both DPI and NR provided evidence of BSA insertion into the gaps on the surface between the antibody molecules. This suggests that BSA adsorption is an excellent method to block the non-specific adsorption of target antigens to the immunoassay test surface. A magnetic tweezer system was designed and built in order to measure the specific antibody/antigen binding force. The antibodies and antigens were used to immuno-link magnetic beads to the experimental surface before the immuno-links were broken by increasing the attractive force between the magnetic tweezers and beads. The force per antibody/antigen immuno-link was estimated to lie between the values of 13.6 pN and 43.8 pN.Immuno-link detachment as a function of time was investigated. It was found that the immuno-link comprised both a strong and a weak interaction. The dissociation constant of the strong antibody/antigen interaction was found to equal 3E-4 /s and had an interaction length of 0.06 nm. The low population of beads bound by the second, weaker interaction meant that it was not possible to obtain accurate values of the dissociation constant and bond length of the second weaker interaction.

612.6