Temperature-Controlled Masking/Unmasking of Cell-Adhesive Cues with Poly(ethylene glycol) Methacrylate Based Brushes

Thin, thermoresponsive polymer coatings that allow to reversibly modulate cell adhesion and detachment are attractive substrates for cell sheet engineering. Usually, this is accomplished by applying thin poly(N-isopropylacrylamide) (PNIPAM) coatings, which allow cell adhesion via nonspecific interactions above the collapse temperature (TT) of the surface-attached polymer and cell detachment upon cooling below TT. This Article presents an alternative, thermoresponsive polymer platform that is based on 2-(2-methoxyethoxy)ethyl methacrylate (MEO2MA) containing copolymer brushes prepared via surface-initiated atom transfer radical polymerization (SI-ATRP). These brushes are interesting as they gradually collapse and dehydrate upon increasing the temperature from 10 to 40 degrees C, yet resist nonspecific adhesion of cells over this entire temperature window. The MEO2MA based brushes presented here were modified via a two-step postpolymerization modification protocol to introduce cell-adhesive RGD containing peptide ligands. The possibility to reversibly control the swelling and collapse of these brush films by varying temperature allows to modulate the effectively available surface concentration of these cell-adhesive cues and thus provides a way to mask/unmask their biological activity. As a first proof of concept, this Article demonstrates that these MEO2MA brush copolymer films enable integrin-mediated adhesion of 3T3 fibroblasts at 37 degrees C and allow release of these cells by cooling to 23 degrees C. The use of cell-adhesive ligands, which can be thermoreversibly masked/unmasked, is attractive as it enables the use of serum-free cell culture conditions. This is advantageous since it avoids possible concerns regarding eventual toxicity and immunological side effects of serum proteins and also provides opportunities to select for particular cell types and for enhanced control over cell stimulation and differentiation.

Mechanochemically Responsive Surfaces and Soft Tissue Adhesive Interfaces Generated via Controlled Radical Polymerization

Nariye Cavusoglu Ataman

Thin coatings applied to surfaces dramatically improve the properties of materials. Thus, they have found application in a broad variety of areas including biomedicine, nanotechnology, bioelectronics and optics, amongst others. Polymer brushes prepared via surface-initiated controlled radical polymerization (SI-CRP) techniques represent a versatile class of thin polymer coatings that provide manifold opportunities to engineer surface and interface properties. Densely grafted polymer brushes prepared via SI-CRP possess several attractive material properties such as low friction coefficients and the ability to prevent biofouling, which are related to the stretched conformation of the surface tethered polymer chains. Those distinctive characteristics of polymer brushes make them highly appealing to engineer the properties of functional interfaces. A first aim of this Thesis is to investigate the mechanochemistry of hydrophilic polymer brushes prepared via surface-initiated atom transfer radical polymerization (SI-ATRP) from silica substrates. The second aim of the Thesis is to explore poly(2-hydroxyethyl methacrylate) (PHEMA) based polymer brushes as soft-tissue adhesives in wet tissue environment. This Thesis is divided into four chapters, which are briefly summarized below. Chapter 1 provides a summary of recent literature that has reported detachment or degrafting of densely grafted hydrophilic polymer brushes from substrates upon exposure to aqueous media. The collective results from these reports suggest that swelling-induced stretching of hydrophilic polymer brushes lead to mechanochemical activation of the bonds near the brush-substrate interface and subsequently facilitates hydrolytic chain cleavage. Chapter 2 aims to shed light on the influence of two fundamental structural polymer brush parameters on the degrafting of surface-tethered, densely grafted polymer chains, viz. (i) the chemical composition of the ATRP initiator that is used to grow the polymer brushes and (ii) the effect of surface curvature. To this end, a series of poly(poly(ethylene glycol) methacrylate) (PPEGMA) and poly(poly(ethylene glycol) methyl ether methacrylate) (PPEGMEMA) brushes were grafted from both flat silica substrates as well as silica nanoparticles. Subsequently, the degrafting of the surface-tethered polymer chains was investigated in cell culture medium and phosphate buffered saline (PBS) using various techniques. The aim of the final two Chapters of this Thesis is less on exploring the chain conformation of polymer chains grafted by SI-CRP, but more to use the ability of SI-CRP to prepare thin polymer films that present a high surface concentration of functional groups to mediate soft tissue adhesion. Chapter 3 describes the preparation of photo-active poly(2-hydroxyethyl methacrylate) (PHEMA) brushes as soft tissue bioadhesives. Tissue adhesion in this Chapter is induced as UV-irradiation of PHEMA brushes converts the initially bio-inert side chain hydroxyl groups of these brushes into (putatively) aldehyde groups, which can react with amine groups present in the tissue. The prepared PHEMA brush coated substrates are biocompatible, which avoids fibrous capsule formation and presents functionalities that can be transformed, on-demand, from a non-reactive, non-adhesive state to a reactive, adhesive state in wet tissue environment. While the photoactivation of the PHEMA side chain functional groups is very efficient, it is not very well defined from a chemistry point of view. Chapter 4 therefore, explores an alternative photoactivation chemistry, which is based on the use of the diazirine motif. These diazirine motifs were incorporated in poly(2-hydroxyethyl methacrylate-co-poly(ethylene glycol) methyl ether methacrylate) (P(HEMA-co-PEGMEMA)) copolymer brushes via post-polymerization modification. These diazirine modified brushes are attractive as they may not only be activated by UV-light but also by electrochemical means.

EPFL2016

Design of amphiphilic nanocapsules based on hyperbranched star-block copolymers for the encapsulation and the controlled release of olfactory compounds

Céline Ternat

Effective encapsulation of small, volatile, weakly water-soluble molecules such as flavors and fragrances is necessary to protect them from degradation, to increase their lifetime, and to improve their water dispersion and fixation depending on the substrate of interest. The aim of this project has been to improve encapsulation and release in order to optimize the performance of fragrance molecules in water-based household (detergents, softeners, etc.) and body care applications (shampoos, lotions, etc.), and fine perfumery applications. More specifically, the aim has been to investigate the effectiveness of "unimolecular micelles" based on amphiphilic multi-arm star-block copolymers with a hyperbranched core with more than 26 functional groups, a hydrophobic inner and a hydrophilic outer shell. These have been prepared from a commercial hyperbranched polyester macroinitiator (HBP) by ring-opening polymerization of ε-caprolactone, followed by the atom transfer radical polymerization (ATRP) of tert-butyl acrylate (tBuA). Hydrolysis of the tert-butyl groups has then been used to convert the poly(tBuA) blocks to poly(acrylic acid) (PAA), resulting in HBP-(PCL)p-(PAA)q pH-dependent amphiphilic star-block copolymers with good control of the molecular weight distribution. These were shown to form stable nanocapsules with a well defined core-shell architecture, as confirmed by thermal and microstructural characterization. The necessity of the core-shell architecture for the effective encapsulation of fragrance molecules in aqueous dispersion has been demonstrated by NMR (nuclear magnetic resonance). The extent of encapsulation reflects the dynamic equilibrium between the free molecules and the fragrance/polymer complex and is dependent on the octanol/water partition coefficient (logP) of the fragrance compounds, as demonstrated with a similar non ionic core-shell architecture HBP-(PBMA)37-(PPEGMA)39 composed of a hydrophobic poly(butyl methacrylate) (PBMA) core and a hydrophilic poly(polyethylene glycol) methyl ether methacrylate (PPEGMA) shell (provided by the Polymer Laboratory of the EPFL). The fragrance loadings in the polymer (HBP-(PCL)p-(PAA)q and HBP-(PBMA)37-(PPEGMA)39), which reached up to 30 wt% depending on the type of the fragrance molecule, were argued to be linked to their solubility in the hydrophobic core of the star-block copolymer. Moreover, under conditions representative of real applications (fine perfumery and softener applications) the star-block copolymers significantly extended the time over which the concentration of certain volatiles remained above the human olfactory threshold. Effective encapsulation and delayed release of small hydrophobic molecules was hence demonstrated to be possible with the present systems. The straightforward synthesis, tailorable chemistry and globular architecture of the star-block copolymers investigated here therefore offer promise for the development of relatively cheap encapsulants with affinities for specific components in fragrance packages, and release triggered by selected substrates according to their surface chemistry.

EPFL2007

RGD-Functionalized polymer brushes as substrates for the integrin specific adhesion of human umbilical vein endothelial cells

Harm-Anton Klok, Paolo Silacci, Nikolaos Stergiopulos, Stefano Tugulu

This report demonstrates the feasibility of surface-initiated atom transfer radical polymerization to prepare thin polymer layers ("brushes") that can be functionalized with short peptide ligands and which may be of use as coatings to promote endothelialization of blood-contacting biomaterials. The brushes are composed of poly(2-hydroxyethyl methacrylate) (PHEMA) or poly(poly(ethylene glycol) methacrylate) (PPEGMA), which do not only suppress non-specific adhesion of proteins and cells but also contain hydroxyl groups that can be used to introduce small peptide ligands. A protocol has been developed that allows functionalization of the brushes with RGD containing peptide ligands resulting in surface concentrations ranging from approximately 0.5-12 pmol/cm(2). At peptide surface concentrations >1-5.3 pmol/cm(2), human umbilical vascular endothelial cells (HUVECs) were found to adhere and spread rapidly. A difference in size and morphology of focal adhesions between HUVECs immobilized on PHEMA and PPEGMA brushes was observed. It is proposed that this is due to the increased ethylene glycol spacer length and hydrophilicity of the PPEGMA brushes, which may lead to increased ligand mobility and reduced ligand-integrin affinity. HUVECs immobilized on the polymer brushes were also found to be able to retain homeostasis when exposed to shear stresses that simulated arterial blood flow.