Alginate-based microcapsules for mammalian cell culture and other biotechnological applications

Véronique Breguet
EPFL, 2007
Thèse EPFL

Résumé

Since life began, nature has been using the envelopment of systems for their protection or for providing a particular reaction space, the enveloping wall displaying additional specific membrane functions. The abundance of examples is quite overwhelming and extends from arboreal fruits and plant seeds to plant seed spores, from the hen egg and its shell to the cell and its membrane/wall. The technique of microencapsulation aims at immobilizing gases, liquids or solids in an envelope. The result is a core contained in a capsule ranging from the nanometer to the millimeter scale. Nowadays, microencapsulation is being studied and developed in many different backgrounds throughout the chemical and life sciences, biotechnology, medicine and related industries. The aims of this thesis were to study the potentials and limitations of alginate-based microcapsules, for biotechnological applications, especially mammalian cell culture. It was shown that the limitations of alginate poly-L-lysine (PLL) microcapsules, commonly used for mammalian cell entrapment, arises from the poor mechanical stability of the polyelectrolytic complex constituting the membrane, and the intracapsular alginate concentration preventing optimal cell growth and core colonization. These limitations may be overcome by finding new techniques preventing the accumulation of alginate in the core, and by reinforcing the membrane through the formation of covalent bonds. To remove alginate from the core of the capsule, the use of an alginate degrading enzyme might be a possibility. However, alginate lyase degrades both gelled, dissolved and complexed forms of alginate. Therefore, this system should be more appropriated for cell release from microcapsules. Another alternative for the formation of alginate-free core microcapsules may be the hydrolysis of an organic-core capsule by a lipase. Aqueous-core capsules surrounded by an alginate matrix were successfully obtained, without accumulation of alginate in the core. However, this system is not suitable for mammalian cell encapsulation due to the toxicity of the process, especially the degradation product resulting from the enzymatic hydrolysis. The third solution to avoid the presence of alginate in the core was the use of the alginate/casein aqueous two-phase system. The combination of these compounds was suitable for the formation of aqueous-core microcapsules, using the jet break-up technique with a concentric nozzle. Casein was not toxic to cells, however precipitated in the presence of Ca2+ (dissolved in the buffer to induce alginate gelation), and hindered further cell growth. Membrane stability can be reinforced by the formation of covalent bonds. Acrylamide monomers polymerization and PLL / propylene-glycol-alginate / BSA transacylation reaction were the two systems studied. The formation of covalent bonds was successful for both systems, and produced reinforced capsules. However, acrylamide monomer, as well as the polymerization process, were toxic for the mammalian cells. Despite the harsh reaction conditions (pH 11), the transacylation reaction allowed cell growth and produced very resistant and stable capsules. As a perspective, the most promising technique seems to be the use of aqueous two-phase systems. The biocompatible nature of the molecules constituting the microcapsules is a great advantage, giving rise to promising issues. Moreover, the possibility to induce polymerization and cross-linking reactions in the membrane is also an advantage of this new type of microcapsules. Due to the harsh condition of reaction, acrylamide or transacylation reactions are probably not the optimal systems, however other covalent systems (genipin or poly(ethylene glycol)-based hydrogels) might be a promising alternative. Encapsulation applications are numerous, and are not only restricted to cell immobilization. The study of the immobilization of rapeseed press-cake in an alginate matrix is an example of a new potential application of alginate-based microcapsules / beads. It was shown to be suitable for removing organic pollutants from waste water, simplifying the process (i.e. phase separation), thus allowing to envisage large-scale industrial applications.

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https://infoscience.epfl.ch/record/110158?ln=fr

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Véronique Breguet
EPFL, 2007
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/110158?ln=fr

À propos de ce résultat

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High-temperature radical polymerization of methyl methacrylate in a continuous pilot scale process

Philip Nising

The present PhD thesis deals with the high temperature polymerization of methyl methacrylate in a continuous pilot scale process. The major aim is to investigate the feasibility of a polymerization process for the production of PMMA molding compound at temperatures in the range from 140 °C to 170 °C. Increasing the process temperature has the advantage of decreasing molecular weight and viscosity of the reaction mixture, thus allowing to reduce the addition of chain transfer agent and to increase the polymer content in the reactor. At the same time, the reaction rates are higher and the devolatilization is facilitated compared to low conversion polymerizations. Altogether, it leads to an improved space time yield of the process. However, increasing the process temperature also has an important impact on both, polymerization kinetics and polymer properties. The first two parts of this work are, therefore, dedicated to the self-initiation respectively the high temperature gel effect observed for the polymerization of MMA at the given temperature range. The self-initiation of MMA is mostly caused by polymeric peroxides that form from physically dissolved oxygen and the monomer, itself. The formation, decomposition and constitution of these peroxides are intensively studied and a formal kinetic is proposed for the formation and decomposition reaction. The polymerization of MMA is subject to a rather strong auto-acceleration, called gel effect, the intensity of which depends on process conditions and solvent content. There are several models proposed in the specialized literature to describe this phenomenon by modifying the termination rate constant as a function of conversion and temperature. The second part of this study contains the evaluation of these models with regards to their applicability to high temperature MMA polymerization as well as the development of a new variant of an existing model, which correctly describes the gel effect in the temperature range of interest as a function of polymer content, temperature and molecular weight. The advantage of this new variant is that it includes all other factors influencing the gel effect, i.e. chain transfer agent, initiator load, comonomer and solvent content, and that it is suitable for the description of batch and continuous processes. A complete kinetic model for the description of the high temperature copolymerization of MMA and MA, containing the results from the first two parts of this work, is established within the software package PREDICI® and validated by means of several series of batch polymerizations. In the third part of this work, a complete pilot plant installation for the continuous polymerization of MMA is designed and constructed in order to study the impact of increasing the reaction temperature on process properties and product quality under conditions similar to those of an industrial-scale polymerization. The pilot plant is based on a combination of recycle loop and consecutive tube reactor, equipped with SULZER SMXL® / SMX® static mixing technology. Furthermore, it is equipped with a static one-step flash devolatilization and a pelletizer for polymer granulation. At the same time, a refined method for inline conversion monitoring by speed of sound measurement is developed and tested in the pilot plant. By means of this technique it is possible to follow the dynamic behavior of the reactor and to measure directly the monomer conversion without taking a sample. The results of several pilot plant polymerizations carried out under different conditions are presented and the impact of temperature, comonomer and chain transfer agent on the thermal stability of the product is analyzed. From these results, the r-parameters for the copolymerization of MMA and MA at 160 °C as well as the chain transfer constant for n-dodecanethiol at 140 °C are determined. Finally, the pilot plant experiments are used to validate the kinetic model established beforehand in PREDICI® for the continuous copolymerization.

EPFL2006

Chargement

Interactive Surfaces Based on Polymer Brushes

Dusko Paripovic

While the bulk structure of a material determines its mechanical properties, its surface plays a key role when interactions with the environment are important. Nowadays materials in bio- and nanotechnology are required to possess very complex functionalities and to interact specifically to the stimuli they receive from their surroundings. Thus, their surface modifications are becoming very demanding. In recent years surface initiated controlled radical polymerization techniques have emerged as very versatile strategies that provide a powerful toolbox to tackle the challenges that are set to material scientists. The attractiveness of these methods lies in the possibility to create well defined surface arrangements of polymer chains, which we refer to as polymer brushes, with precise control over thickness, composition and architecture. In addition, these techniques can be applied to very challenging substrates with respect to the chemical composition and geometry, which also includes porous materials. This Thesis, therefore, exploits the possibilities that surface-initiated controlled radical polymerization techniques offer to finely tune interfacial properties of materials and render them capable to interact with chemical and biological species in a desired way. Its paramount aim is to demonstrate how the functionalities and geometry of a polymer brush matrix can be employed to influence inorganic film deposition using synthetic, biomimetic and purely biological mechanism or enhance polymer brushed stability in aqueous media. This Thesis is divided into five distinct chapters, which will be briefly summarized in following paragraphs. Chapter 1 describes the preparation of polymer brushes and strategies that are used to control their chemical composition and architecture. Additionally, it will give an overview on the use of brushes as cell adhesive surfaces as well as templates for the production of nanoparticles and thin inorganic films. Chapter 2 explores a new strategy to guide the chemical solution deposition of thin, microstructured metal films. The proposed strategy is based on the use of poly(2-(methacryloyloxy)ethyl ammonium chloride) (PMETAC) brushes grown via surface-initiated atom transfer radical polymerization as a template. Thin films are prepared by first loading the PMETAC brushes with an appropriate precursor, followed by its reduction by NaBH4 and finally an oxygen plasma treatment to remove the stabilizing polymer brush matrix and generate the desired thin metallic film. Of particular interest is the question whether the thickness and lateral dimensions of the deposited metallic films can be controlled by micropatterning the polymer brush template and varying the brush thickness. In addition, this concept will be extended to the preparation of bimetallic (gold/palladium) films using a single polymer brush matrix. A similar strategy is explored in Chapter 3 to control the deposition of thin calcium carbonate films using a biomimetic process. The process is characterized by the stabilization of amorphous calcium carbonate, the geometry and localication of which can be controlled by the poly(methacrylic acid) brush template. A special focus of this Chapter is to examine the influence of the polymer brush thickness on the mineral deposition and to determine to which extent is the mineral phase is integrated into the polymer brush film. The aim of Chapter 4 is to develop a general approach for the modification of implantable materials with a polymer brush based coating that promotes bone formation. The proposed coatings are prepared via surface-initiated copolymerization of 2-hydoxyethyl methacrylate and 2-(methacryloyl)ethyl phosphate, which results in a thin hydrogel layer that mimics the negatively charged matrix macromolecules involved in natural bone formation. To further emulate the properties of the natural bone extracellular matrix, the coatings will be functionalized with the cell adhesive GGGRGDS peptide. The ability of the proposed coatings to induce bone formation is investigated in in vitro experiments on MC3T3-E1 pre-osteoblasts and evaluated using an ALP and alizarin red assays. Finally, Chapter 5 focuses on studying the parameters that could prevent the hydrolytic cleavage of Si-O bond, which tethers the polymer brushes grafted from SiOx in aqueous media. In the first part of the study, the length of the organosilane initiator's alkyl spacer will be varied, in order to evaluate to which extent it can insulate the site that anchors the hydrophilic polymer brush to the substrate. In the second part, a short, hydrophobic block will be introduced between the silicon oxide substrate and the hydrophilic polymer in order to more efficiently protect the underlying Si-O bond from the surrounding aqueous media and prevent the chain detachment.

EPFL2011

Chargement

In recent years sophisticated biomaterials have made a significant impact on our understanding of cellular behavior, particularly in the fields of stem cell research and tissue engineering. Nevertheless, the promising potential of stem cells for regenerative medicine has remained largely unmet. One reason for such limitations could be that there is still incomplete understanding of stem cell behavior due to a lack of advanced in vitro tools suitable to achieve adequate control over cellular processes. By mimicking the dynamic and complex biophysical and biochemical interactions between cells and their natural extracellular matrixes (ECMs), it is possible that we may bridge this gap between current limited in vitro models and complex in vivo organisms. In this thesis, an innovative class of biomaterials is presented that enables the flexible in vitro recapitulation of the dynamic biochemical and biophysical signaling involved in controlling cell fate. Such systems of increasing fidelity to real physiological processes could bring new insights into fundamental cell biology as well as bring us to closer towards cell-based therapeutics applications. In order to achieve a dynamic artificial ECM (aECM), we designed chemical schemes which would allow us to control the biochemical and biophysical properties of the hydrogel in space, time and intensity. The chosen concept is built on a synthetic hydrogel providing static physicochemical support, while spatiotemporal control over a single or multiple signals is achieved by spatiotemporal photoactivation reactions within this hydrogel. Indeed, by modulating the duration, location and intensity of illumination, desired heterogeneities in biochemical and biophysical signal can be introduced in the otherwise homogeneous and static hydrogel network. To implement the designed hydrogel photo-patterning tool, new chemical components were synthesized. Synthetic hydrogels based on poly (ethylene glycol) (PEG) were utilized due to their inert properties, cell biocompatibility and lack of unspecific protein binding. Biochemical signal tethering was rendered spatiotemporally controllable by adding photosensitivity to the existing enzyme-based crosslinking scheme. This was achieved by functionalizing one of enzymatic substrate with a photo-labile “caging” moiety, thereby preventing crosslinking to occur until light illumination. This caged substrate was incorporated into the hydrogel network and served as a light-controllable and specific ligand-binding site. Importantly, it was possible to photo-pattern proteins, which are much complex than peptide-based biomolecules, and their bioactivity was fully preserved with this site-specific immobilization scheme. It was also possible to pattern biophysical cues by making the Michael-type (MT) addition reaction for crosslinking PEG-based hydrogel photosensitive. In this case, the thiol moieties of one of the reactive PEG macromers undergoing crosslinking, were equipped with a caging group which prevented its susceptibility to the counter-reactive functionality, the vinyl sulfone group. Thus, the crosslinking density of the hydrogel backbone could be controlled by light, which was directly translated into differential patterns of hydrogel stiffness. Using this approach, user-defined biochemical and biophysical patterns and even gradients could be obtained in the spatiotemporal manner within the same hydrogel. The crosslinking reaction is the critical parameter in the success of hydrogel photo-patterning, and must rely on a well-controlled and highly selective chemical scheme. Therefore, we also developed a novel enzyme-based cross-linking scheme for synthetic PEG hydrogels. The reaction originates from the naturally occurring post-translational modification of proteins by phosphopantetheine (Ppant) group performed by a family of enzymes known as Ppant transferases (PPTases). By synthesizing biochemical components of this reaction, we implemented a PPTase-catalyzed reaction to form and bio-functionalize PEG hydrogel. The utility of the developed hydrogel platforms was determined in the context of 2D and 3D cell culture. Photo-directed patterns of a cell-adhesive fibronectin fragment triggered adhesion and spreading of muscle progenitor cells, a phenomenon which occurred only within the areas of patterned signaling protein. A photo-patterned elasticity gradient was used to direct mesenchymal stem cell spreading and migration. Finally, the PPTase-based hydrogel was proven to be suitable for 3D culture, as shown by encapsulation of primary human fibroblasts. In this thesis, we demonstrated that a combination of chemical schemes could be assembled to achieve a functional materials toolbox which would begin to reconstruct the complexity of the dynamic in vivo ECM. Such a tool is expected to contribute to the field of cell biology by allowing us to study questions which previously could not be addressed in vitro, and could ultimately contribute to cell-based regenerative medicine.

EPFL2012

Chargement

EPFL2012

Interactive Surfaces Based on Polymer Brushes

Dusko Paripovic

EPFL2011

High-temperature radical polymerization of methyl methacrylate in a continuous pilot scale process

Philip Nising

EPFL2006