Design of Smart Polymeric Materials with Responsive / Adaptive Adhesion Properties

Biehlig, Ekaterina

11 July 2013

Adhesion between different objects is happening everywhere. Without it, simple procedures like walking or holding something in a hand or attaching a postage stamp would be impossible. The life itself depends on adhesion on all levels, starting from the interactions between the living cells. Adhesion between two substrates is a complex phenomenon, which at present is still not well understood. There are several factors determining the strength of adhesion: (i) molecular interactions at interface, (ii) mechanical properties of adhesive, and (iii) area of contact between adhesive and probing surface. Two surfaces are tacky when they possess the right balance between these factors. Controlling the adhesion of materials is important in many fields ranging from industrial purposes to biomedical applications and everyday usage. There is a demand for “smart” materials with integrated functionalities that make them responsive, switchable, biocompatible, anti-bacterial, more energy efficient, or autonomous. In particular, materials for such cutting-edge applications like cell culture, drug delivery, tissue engineering, biosensors, anti/biofouling, microfluidics, climbing robots, sport equipment and many others require adjustable/tuneable adhesive properties. Many efforts were directed towards fabrication of materials with either weak or strong adhesion depending on the field of application. However, design of “smart” surfaces with reversibly switchable/controllable adhesion is still a highly challenging task. Therefore, the thesis aims on design of smart polymeric materials with responsive / adaptive adhesion properties. For this, fabrication and investigation of two types of switchable polymer layers based on stimuli-responsive polymer brushes will be performed. The first group is dealing with thermoresponsive polymer brushes: poly-(N-isopropylacrylamide) and two types of biocompatible polyethylene glycol-based systems. These polymer layers undergo phase transition below and above LCST between hydrophilic and hydrophobic states. The second part of the work is related to solvent-responsive comb-like and block copolymer brushes consisted of hydrophilic PEG and hydrophobic PDMS biocompatible and biodegradable polymers.

Adhäsion

Polymerbürste

schaltbare Adhäsion

Rasterkraftmikroskop

Adhesion

switchability

adaptation

polymer brushes

atomic force microscope

colloidal probe technik

tack test

ddc:540

rvk:VK 8007

Photochemische Fixierung von Strukturen in Grenzflächen mit polymeren Bürsten

Hoffmann, Frank

08 February 2008

Binäre Polymerbürsten bestehen aus zwei verschiedenen Polymertypen, die nebeneinander auf dem gleichen Trägermaterial verankert sind. Wenn diese Polymere unterschiedliche Benetzungseigenschaften haben, können damit schaltbare Oberflächen produziert werden. Abhängig vom Lösungsmittel, dem man die binäre Polymerbürste aussetzt, streckt sich entweder das hydrophile oder das hydrophobe Polymer zum Lösungsmittel hin, während die zweite Komponente nahe der Oberfläche verbleibt. Durch diese vertikale Phasenseparation kann temporär eine bestimmte Oberflächeneigenschaft erzeugt werden. Allerdings verschwindet diese sofort wieder, wenn ein anderes Lösungsmittel die binäre Bürste benetzt, sei es durch direkten Kontakt oder über die Gasphase. In der vorliegenden Arbeit wurde untersucht, ob es möglich ist, neuartige schaltbare binäre Polymerbürsten bestehend aus einem hydrophilen und einem hydrophoben Polymer angebunden auf Siliziumwafern herzustellen, deren Schaltfähigkeit durch photochemische Vernetzung unterbunden werden kann. Geprüft worden ist unter anderem, inwiefern sich hydrophober und hydrophiler Zustand der Schicht fixieren lassen und ob daraus resultierend, eine entsprechende Strukturierung der Oberfläche nach Bestrahlung durch eine geeignete Fotomaske oder durch fokussiertes Licht nachweisbar ist. Als hydrophobe Komponente wurden photovernetzbare Styren/2-(4’-Styryl)-inden-Copolymere verwendet, als hydrophile Komponente kam Polyvinylpyridin zum Einsatz. Mit einem speziellen Oberflächeninitiator konnten durch „Grafting from“ binäre Polymerbürsten mit bis zu 300 nm Schichtdicke erzeugt werden. Es ist gelungen, diese schaltbaren Schichten durch selektive photochemische Vernetzung einer der Bürstenkomponenten im hydrophilen oder im hydrophoben Zustand zu fixieren, was durch Kontaktwinkelmessung nachgewiesen werden konnte. Wie beabsichtigt, verlieren dabei die vernetzten Bereiche ihre Schaltfähigkeit. Es ließen sich feine Oberflächenstrukturen mittels Bestrahlung durch eine Fotomaske erzeugen, die sichtbar werden, wenn man sie mit Wasser benetzt bzw. Wasserdampf aussetzt.

Polymerbürsten

Photovernetzung

Photodimerisierung

mikrostrukturierte Oberflächen

schaltbare Oberflächeneigenschaften

polymer brushes

grafting-from

photocrosslinking

photodimerization

surface microstructures

switchable surface properties

ddc:540

rvk:VK 8007

Fabrication and Study of Switchable Polymer Layers with Hydrophobic/Hydrophilic Behavior / Herstellung und Untersuchung schaltbarer Polymerschichten mit hydrophobem/ hydrophilem Charakter

Motornov, Mikhail

07 November 2004

The framework of this thesis aims to fabricate materials, which change surface characteristics in response to environmental conditions. This response may be employed to improve material characteristics as adhesion, wettability, interaction with cells etc. The mixed brushes introduce adaptive and switching behavior in different surrounding media. Two main approaches were employed to fabricate mixed polymer brushes: "grafting to" and "grafting from". Mixed PS/PVP polymer brushes were synthesized via step-by-step grafting of these two polymers from polyamide (PA) surfaces. NH3 plasma was used for the introduction of amino and OH functionalities on PA surfaces with following attachment of azo initiator of radical polymerizaton. The mixed brushes prepared on the surface of PA textiles combine both the switching effect and effect of composite surface (i.e. micrometer scale roughness) which substantially amplifies the switching range. Mixed polymer brushes prepared from P(S-b-2VP-b-EO) and P(S-b-4VP) block copolymers were grafted to both the flat surface of Si wafers and to the surface of silica nanoparticles via quaternization reaction of the pyridine nitrogen. This one step grafting technique has a substantial advantage over the multistep grafting of mixed polymer brushes. We have demonstrated that combination of the two level hierarchical organization of polymer films at macroscopic and nanoscopic levels resulted in the formation of self adaptive surfaces switchable in controlled environment from ultra-hydrophobic to hydrophilic energetic states. The PFS/PVP mixed brush was grafted onto the pre-treated PTFE surface (plasma etching) with the needle like topography. The size of vertical needles was at micron scale. If the brush is switched to the hydrophobic state the layer has shown a unique ultra-hydrophobic behavior (complete non-wetting) with the contact angle approaching value of 160o. If the mixed brush was switched into the hydrophilic state the surface became completely wetted due to the capillary forces in the pores formed by the needle like structure. Thus, the surface can be either highly wettable or completely non-wettable with the self cleaning properties.

Hydrophob

Intellegente Materialien

Polymerbürsten

Polymere Grenzflächen

Hydrophobic

Intelligent Materials

Polymer Brushes

Polymer Interface

ddc:540

rvk:VK 8007

Grenzflächen

Intelligenter Werkstoff

Lipophile Verbindungen

Polymere

Μελέτη διεπιφανειακών φαινομένων με την μέθοδο διέγερσης επιφανειακών πλασμονίων

Κουτσιούμπας, Αλέξανδρος

26 June 2009

Αντικείμενο της παρούσας διδακτορικής διατριβής αποτελεί η ανάπτυξη της πειραματικής Μεθόδου Διέγερσης Επιφανειακών Πλασμονίων (Surface Plasmon Resoanance, SPR) για τη μελέτη διεπιφανειακών φαινομένων και ειδικότερα των ιδιοτήτων ισορροπίας και της κινητικής της προσρόφησης πολυμερών και ολιγομερών στη διεπιφάνεια υγρού / στερεού. Στα πλαίσια της διατριβής, κατασκευάσθηκε εξ’ αρχής πειραματική διάταξη συντονισμού επιφανειακών πλασμονίων, η οποία χρησιμοποιήθηκε για την μελέτη του φαινομένου της προσρόφησης. Παράλληλα αναπτύχθηκε θεωρητικό υπόδειγμα και υπολογιστικά εργαλεία ανάλυσης των πειραματικών μετρήσεων. Με τη χρήση της πειραματικής διάταξης μελετήθηκε η διαδικασία της προσρόφησης γραμμικών και αστεροειδών πολυμερών στη διεπιφάνεια υγρού / στερεού όπως επίσης και τασιενεργών ολιγομερών τα οποία σχηματίζουν Αυτό-οργανούμενα Μονομοριακά Στρώματα (Self Assembled Monolayers) σε επιφάνειες οξειδίου του αλουμινίου. Επιπλέον διερευνήθηκε η επίδραση της αρχιτεκτονικής των πολυμερικών αλυσίδων σε σχέση με την ικανότητά τους να αυτο-οργανώνονται σε στρώματα πολυμερικών ψηκτρών (polymer brushes). Τα πειραματικά αποτελέσματα συγκρίνονται με μετρήσεις οι οποίες έγιναν με τη μέθοδο ανάκλασης νετρονίων. Για την κατανόηση των μικροσκοπικών μηχανισμών που υπεισέρχονται κατά την αυτό-οργάνωση των πολυμερών, γίνεται χρήση θεωρητικών υποδειγμάτων κλίμακας και υπολογιστικών προσομοιώσεων Monte Carlo. Περαιτέρω, μέσω της χρήσης λεπτών στρωμάτων νανο-πορώδους αλουμίνας, προτείνεται μια νέα παραλλαγή της μεθόδου διέγερσης επιφανειακών πλασμονίων η οποία όπως αποδεικνύεται, αυξάνει την ευαισθησία της μεθόδου κατά μια τάξη μεγέθους, στην περίπτωση της ανίχνευσης της προσρόφησης ολιγομερών. Η διατριβή παρουσιάζει ολοκληρωμένα τη χρήση της μεθόδου διέγερσης επιφανειακών πλασμονίων για την αναλυτική μελέτη της προσρόφησης μορίων σε επιφάνειες. Η επέκταση της μεθόδου με τη χρήση νανο-δομημένων υλικών ανοίγει τον δρόμο για πλειάδα νέων εφαρμογών στο πεδίο της ανίχνευσης προσροφημένων μορίων από διαλύματα ιδιαίτερα χαμηλών συγκεντρώσεων. / The objective of the present PhD thesis is the development of the experimental Surface Plasmon Resonance (SPR) method, for the study of interfacial phenomena such as the equilibrium properties and kinetics of polymer and oligomer adsorption at the liquid / solid interface. For the purposes of this work a custom-made experimental apparatus has been build and used for the acquisition of SPR experimental results. A theoretical model and various computational tools were also developed for the analysis of the experimental data. With the aid of this apparatus, the adsorption process of linear and star-like polymers at the liquid / solid interface was studied together with the self-assembly of functional oligomer monolayers on alumina surfaces. In addition, the effect of different chain structure (molecular architecture) on the formation of polymer brush layers was investigated. The experimental results are compared with measurements by neutron reflectivity experiments. For the investigation of the microscopic mechanisms that are involved in the polymer self-assembly, scaling theoretical calculations and Monte Carlo computer simulations were performed. Furthermore, by the use of thin nano-porous alumina films, a new variation of the SPR method is proposed. It is demonstrated, that this improved method is characterized by over one order of magnitude higher sensitivity in the case of the detection of adsorbed oligomers. The present thesis describes in detail the use of the SPR method for the analytical study of molecular adsorption on surfaces. The improvement of the SPR technique by the use of nano-structured materials opens new prospects for many new applications in the field of molecular detection in very dilute solutions.

Προσρόφηση

Πολυμερή

Πολυμερικές ψήκτρες

Προσομοίωση

Πορώδης αλουμίνα

Οπτικός ανιχνευτής

Αστεροειδή πολυμερή

541.335

Surface plasmons

Adsorption

Polymers

Polymer brushes

Simulation

Porous alumina

Optical sensor

Star polymers

Surface modification of titanium substrates with polymer brushes to control cell adhesion for bioapplications

Raynor, Jenny E.

17 November 2008

Modification of the surface chemistry of materials used as implants in biomedical applications affords the ability to control cell adhesion, prevent inflammation and enhance integration with the host. Titanium and its alloys are strong and lightweight thereby making them desirable for applications such as hip and knee replacements, dental implants, and cardiac pacemaker implants. However, the lifetime of these implants is often limited by poor incorporation into the surrounding bone which results in loosening and wear. In order to overcome these limitations we have studied the modification of titanium substrates with a self-assembled monolayer that can be used to perform surface-initiated atom transfer radical polymerization (SI-ATRP) of a monomer to afford polymer brushes that effectively prevent the adhesion of cells. In addition, the polymer brushes afford the ability to tether a peptide sequence. Specific peptides containing adhesion sequences have been tethered to the polymer brushes. The resulting surfaces promote cell adhesion and osteoblast differentiation, thereby increasing bone tissue formation around the implant resulting in better incorporation of the implant.

Bioactive ligands

Peptide tethering

Non-fouling

SAMS

Surface modification

Polymer brushes

Titanium alloys

Surfaces (Technology)

Cell adhesion

Biomedical materials

Protective coatings

Polymers in medicine

Déformation et agrégation sous écoulement de globules rouges et vésicules en microcanaux / Deformation and aggregation in flow of red blood cells and vesicles in microchannels

Lanotte, Luca

17 May 2013

Les globules rouges (GR) jouent un rôle clé dans l’exercice de fonctions physiologiques du corps humain. Dans la microcirculation, par exemple, où ils s’écoulent dans des capillaires de diamètre comparable à leurs mêmes dimensions, les érythrocytes sont responsables de l’échange d’oxygène et nutriments avec les tissus. Il a été montré dans de nombreux articles scientifiques que des dysfonctionnements dans les propriétés des GRs et des dommages du tissu endothélial, en particulier au niveau de la couche de glycoprotéines qui le recouvre (glycocalyx), sont la cause principale des maladies vasculaires telles que la thrombose, le diabète et l’athérosclérose. En conséquence, la connaissance des propriétés mécaniques et rhéologiques qui permettent aux érythrocytes de se déformer et de s’organiser en agrégats dans les vaisseaux sanguins permettrait de mieux comprendre les mécanismes qui gouvernent la circulation du sang et, par conséquent, de faciliter le diagnostic des états pathologiques.Dans cette thèse l’attention s’est concentrée sur deux thèmes principaux : l’agrégation des GRs pendant l’écoulement dans les microcapillaires et la fonction du glycocalyx dans la microcirculation. Même si le sujet est à la fois essentiel et d’intérêt scientifique considérable, une analyse quantitative de la formation d’agrégats de GRs (cluster) n’avait pas encore été réalisée. Dans une première phase de ce projet de thèse des expériences in vitro ont été réalisées sur des suspensions de GRs avec un hématocrite d’environ 10%, afin d’observer leur tendance à s’agréger au cours du déplacement dans des tubes en verre de diamètre égal à 10 µm. Ce comportement a été évalué en fonction de la pression imposée et du temps de résidence dans de microcanaux, en mesurant la longueur des clusters et leur composition numérique. Le but principal a été comprendre le type d’interaction entre les cellules composantes un cluster : il s’agit d’une interaction purement hydrodynamique ou des autres forces sont également impliquées ? Les résultats expérimentaux présentés dans cette thèse clairement montrent que la véritable force motrice du phénomène est la pression imposée dans les capillaires. Cette approche microfluidique permet de jeter les bases pour le développement de dispositifs cliniques et diagnostiques.Dans la deuxième partie du projet, une campagne expérimentale a été réalisée sur microcapillaires en verre revêtus de brosses de polymères, afin de simuler les conditions in vivo dans la microcirculation. Il a été établi avec certitude que le lumen des vaisseaux sanguins est recouvert d’une couche de glyco-polymères (glycocalyx) liés à la membrane des cellules endothéliales qui tapissent leurs parois. La compréhension du rôle hydrodynamique du glycocalyx est essentielle pour expliquer le lien entre le dysfonctionnement cette couche et le maladies vasculaires et pour développer des tests basés sur la microfluidique, capable de représenter correctement les interactions entre les parois et le composants sanguins. Des couches nanométriques de poly-hydroxyéthylméthacrylate (pHEMA) ont été produites par ce qu’on appelle la technique grafting-from et, après une caractérisation approfondie, utilisées pour revêtir les surfaces internes de canaux en verre de 10 µm de diamètre. Dans cette thèse, nous présentons les profils de vitesse obtenus en étudiant la circulation dans des tubes recouverts avec brosses de différentes épaisseurs. On montre que il y a une augmentation de la résistance à l’écoulement dans les canaux recouverts et que la réduction de la vitesse est significativement plus grande par rapport à ce qui se produirait à la suite d’une simple réduction géométrique du lumen disponible. De plus, à partir de l’observation de l’écoulement de GRs à l’intérieur des microcapillaires recouverts par les brosses de polymère, il a été constaté que la vitesse et la déformabilité des GRs dépendent strictement de la présence de la bio-couche sur les parois des microtubes. / The investigation of red blood cells (RBCs) dynamics in blood circulation is one of the most innovative and intriguing challenge of science nowadays since erythrocytes are involved in fundamental physiological functions of human body. In particular, RBCs play a key role in microcirculation where narrow dimensions of vessels (comparable to cell size) promote a close contact between cells and capillary walls and, as a consequence, the exchange of oxygen between blood and tissues. It is well established in scientific literature that disorders in RBCs properties and damages of endothelium are the main causes of common vascular diseases, such as thrombosis, diabetes and atherosclerosis. Thus, the full understanding of mechanical and rheological properties of RBCs would allow not only to shed light on the mechanisms leading blood circulation, but also to develop increasingly reliable diagnostic devices. In this thesis, the attention is mainly focused on two topics: RBCs aggregation in microcapillaries and the role of glycocalyx in microcirculation. As regards the first theme, despite the considerable scientific importance, a quantitative analysis of RBCs aggregates formation (clustering) in microvessels is still lacking. In a first phase of the project, experimental investigations in vitro have been performed on RBCs suspensions with hematocrit almost equal to 10% to observe their tendency to aggregate during the flow in glass microtubes (diameter equal to 10 µm). RBCs aggregation has been evaluated as a function of the fixed pressure drop (Δp) and the residence time in microchannels by measuring clusters length and their statistical composition. The main aim of the experiments was to clarify the nature of the force acting on consecutive cells in a cluster: is it a pure hydrodynamic interaction or are other kinds of forces involved too? The experimental results presented in this thesis clearly show that the driving force of the phenomenon is the imposed Δp in the microtubes. The outcomes of these investigations suggest that microfluidics can represent an efficient means to develop clinical and diagnostic tests on healthy and pathological blood.In the second part of the thesis, an experimental campaign was performed on glass capillaries lined with polymer brushes to mimic in vivo conditions in microvascularity. Several scientific papers show that the lumen of vascular vessels is coated by a layer of glycopolymers linked to the endothelial cells. The full understanding of the hydrodynamic role of glycocalyx is essential to elucidate the link between its dysfunctions and vascular diseases. Moreover, it would be helpful to develop innovative clinical tests by microfluidics that could take in account the interactions between “hairy” walls and blood components. Nanometric brushes of poly-hydroxyethylmethacrylate (p-HEMA) have been produced by a grafting-from technique and, after characterization, they have been used to line internal surfaces of silica capillaries with 10 µm diameter. Here, we present the experimental results obtained by measuring velocity profiles in glass channels bearing polymer brushes of different thickness. An increasing flow resistance is observed in hairy channels as a function of brush thickness. The measured velocity decrease is significantly higher than expected from a simply geometrical reduction of the available capillary lumen. Furthermore, the observation of RBCs flow in such brush-coated channels reveals that cells velocity and deformation are closely depending on the presence of the bio-layer on the internal walls of the capillaries.

Hydrodynamique

Écoulement sanguin

Aggrégation des globules rouges

Brosses de polymère

Interactions globules/parois

Hydrodynamics

Blood flow

Red blood cell clustering

Polymer brushes

Cell/wall interactions

530

Functional surface-initiated polymers : device applications and polymerization techniques

Hamelinck, Paul Johan

January 2008

Self-assembled monolayers and surface-initiated polymer, or polymer brushes, have attracted attention as they form dense layers with much higher structural order than bulk or solution polymers. Another field of research which has emerged over the last two decades is the field of organic and polymer electronics. In this field molecular order and surface modification are of major influence on the device performance, hence that both self-assembled monolayers as polymer brushes have been investigated to find applications in organic electronic devices. After an introduction into the field self-assembled monolayers, polymer brushes and organic electronics, the first part of this thesis focusses on three applications of surface modification techniques for applications in devices. Alignment of the active material is crucial for high mobilities in organic electronics. Chapter 2 discusses the synthesis of a liquid crystalline surface-initiated polymer and its application to induce strong homeotropic alignment. The alignment is homogeneous over large areas and can be patterned by combining the polymerization with soft lithographic techniques. Mobilities of organic electronic materials can also be strongly influenced by dopants in the material. In field-effect transistors the positioning of the dopant is thought to be crucial, as the conductance predominantly takes place in only a small channel near the dielectric interface. In chapter 3 dopant functionalized monolayers and polymer brushes are presented which enable the localized deposition of dopants in the channel of organic transistors. It is shown that the mobility of charges and hence the device performance is affected by the introduction of this dopant layer. Polymer brushes have been suggested for the fabrication of highly ordered semiconducting polymers. In chapter 4 the use of a thiophene functionalized polymer brush is shown, that can be used as a template for the subsequent growth of highly conjugated surface grafted polythiophene layers. Thick polythiophene layers are obtained, that are low in roughness and show photoluminescence and polychromism upon doping. The second part (chapter 5 and 6) of this thesis presents new techniques for surface polymerizations. It is attractive to investigate reduction of reactor volume for polymer brush growth. Chapter 5 discusses a method to achieve volume reduction by back-filling the superfluous volume with beads. It is found that this influences the polymerization kinetics significantly. The combined advantages of less volume and enhanced reaction speeds enable reduction of the total amount of monomer needed by up to 90%. Chapter 6 presents a controlled way to convert initiators for atom transfer radical polymerization into initiators for nitroxide mediated polymerization. In this way mixed polymer brushes and block co-polymer brushes become accessible. This combination makes it an attractive tool to fabricate complex polymer architectures. The technologies used in this thesis show that the synthesis of polymer brushes enable the fabrication of complex architectures without the wastes normally associated with surface-initiated polymers. Combined with several functionalized polymer brushes with properties that enhance order, influence mobility or serve as template for the growth of surface attached conjugated polymers this shows the high potential for the application of surface-initiated polymers in organic electronics.

540

Senzitivní vrstvy pro optické biosenzory a proteinové čipy / Sensitive Layers for Optical Biosensors and Protein Chips

Rodriguez Emmenegger, César

January 2012

Sensitive layers for optical biosensors and protein chips The goal of this thesis was the development of sensitive surfaces for optical affinity biosensors detecting in complex biological media. The practical application of these surface-based technologies has been hampered by protein fouling from biological media, in particular blood plasma, where the vast majority of relevant analytes are present. The work of the thesis was centred in three main foci:  Design and preparation of antifouling and non-fouling surfaces  Evaluation and conceptualisation of their resistance to fouling from blood plasma and serum as well as other biological fluids  Preparation of sensitive layers for detection in complex biological media Three approaches were used to prepare protein resistance surfaces, i) ω-functional self-assembled monolayers (SAM), ii) end-tethered polymers and iii) polymer brushes prepared by surface initiated controlled radical polymerisation. Investigation of proteins in the blood plasma deposits on PEG- based surfaces revealed that some fouling is unavoidable in PEG-based surface modifications. A novel type of non-fouling polymer brushes based on poly[N-(2-hydroxypropyl) methacrylamide] challenged the accepted ideas for the design of protein resistant surfaces. For the first time a...

Investigation of Polymer Systems in Solutions with Electron Microscopy and Scattering Methods

Schellkopf, Leonard

13 May 2015

This work is focused on the visualization and thus in the aid in finding explanations for the behavior of polymer structures as they exist in solution. For this aim, preparation and imaging techniques based on cryo-TEM protocols were developed for a large variety of polymeric specimens using new commercially available devices and the results were compared with the findings of other means of structural investigations. The systems used in this work were chosen, as their investigations can be adapted to other polymer systems by slight adaptation of the preparation procedures.

info:eu-repo/classification/ddc/540

ddc:540

Biofunctionalization of Polymer Brush Surfaces

Psarra, Evmorfia

10 June 2015

Surface engineering of tailored materials with adjustable characteristics in relation to biological environment, is one of the main prerequisites for biotechnological applications. In recent years, advanced surface coatings in the nanometer range have drawn big attention. A special category of this group are stimuli responsive polymers tethered by one functional end to the surface. When the surface grafting density is big enough, the polymer chains are forced to stretch away from the interface due to excluded volume effects, creating a so called polymer brush. Nano-scaled polymer brushes are advantageous due to their nanostructure, which can be comparable to biological species, and their collaborative response to external stimuli. Moreover, the material design parameters such as chemistry, surface topography, charge, and surface wettability can be adjusted by using the appropriate polymer, or a combination of polymers with respect to the desired material performance. In case of binary polymer brushes, the materials' properties are switched between the properties of two constituent polymers. Besides, upon switching of external stimuli, biomodified binary polymer brushes can hide or expose biofunctionalities, on demand. Hence, they are classified as smart biomaterials' surface coatings.

info:eu-repo/classification/ddc/540

ddc:540