Synthesis strategies to extend the variety of alginate-based hybrid hydrogels for cell microencapsulation

Sandrine Gerber, François Rémi Pierre Noverraz, Solène Marcelle Françoise Marie Passemard, Luca Szabó, Christine Wandrey
Amer Chemical Soc, 2017
Journal paper

Abstract

The production of hydrogel microspheres (MS) for cell immobilization, maintaining the favorable properties of alginate gels but presenting enhanced performance in terms of in vivo durability and physical properties, is desirable to extend the therapeutic potential of cell transplantation. A novel type of hydrogel MS was produced by straightforward functionalization of sodium alginate (Na-alg) with heterotelechelic poly(ethylene glycol) (PEG) derivatives equipped with either end thiol or 1,2-dithiolane moieties. Activation of the hydroxyl moieties of the alginate backbone in the form of imidazolide intermediate allowed for fast conjugation to PEG oligomers through a covalent carbamate linkage. Evaluation of the modified alginates for the preparation of MS combining fast ionic gelation ability of the alginate carboxylate groups and slow covalentcross-linking provided by the PEG-end functionalities highlighted the influence of the chemical composition of the PEG-grafting units on the physical characteristics of the MS. The mechanical properties of the MS (resistance and shape recovery) and durability of PEG-grafted alginates in physiological environment can be adjusted by varying the nature of the end functionalities and the length of the PEG chains. In vitro cell microencapsulation studies and preliminary in vivo assessment suggested the potential of these hydrogels for cell transplantation applications.

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Sandrine Gerber, François Rémi Pierre Noverraz, Solène Marcelle Françoise Marie Passemard, Luca Szabó, Christine Wandrey
Amer Chemical Soc, 2017
Journal paper

Abstract

Official source

https://infoscience.epfl.ch/record/230143?ln=en

About this result

Related concepts (12)

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Tuning the Properties of Hydrogel Microspheres by Adding Chemical Cross-linking Functionality to Sodium Alginate

Françoise Borcard, Léo Bühler, Virginia Crivelli, Sandrine Gerber, Redouan Mahou, François Rémi Pierre Noverraz, Solène Marcelle Françoise Marie Passemard, Christine Wandrey

Two novel types of hydrogel microspheres (MS) are presented. First, one-component microspheres (1-comMS) were produced from sodium alginate (Na-alg) equipped with thiolfunctionalized hydroxyl groups. The functionalization pathway included the conversion of Na-alg into tetrabutylammonium alginate, insertion of new carboxyl groups, grafting of α-amine-ω- thiol poly(ethylene glycol), and restoration of the sodium salt. This modification conserves all original carboxyl groups of Na-alg and allows for covalent disulfide bond formation in addition to ionic cross-linking. Second, two-component microspheres (2-comMS) were obtained from a mixture of Na-alg and Na-alg functionalized with cysteamine. This functionalization was achieved by grafting cystamine dihydrochloride on some carboxyl groups followed by the reduction to cysteamine. Using the one-step MS formation process developed for both MS types, very fast ionic gelation with calcium ions conserves the spherical shape of the polymer solution droplets upon extrusion into the gelation bath, while simultaneously occurring slow covalent cross-linking reinforces the hydrogels. The physical properties of both MS types are adjustable by varying the polymer concentration, the degree of grafting, and the mixing ratio. In vitro cell microencapsulation studies confirmed the cytocompatibility of 1-comMS and 2-comMS.

American Chemical Society2015

Load-bearing tissues such as articular cartilage or meniscus are not infallible. They might fail due to trauma, over-solicitations, or diseases, which could subsequently alter the mobility of the patient. Repairing these damaged tissues in a minimally invasive way is nowadays widely studied. Hydrogels are promising for repairing soft tissues. However, trying to reproduce the highly hierarchical microstructures of load-bearing tissues is extremely complicated. In fact, conceiving hydrogels with optimal properties for specific applications is challenging as most of the hydrogel's properties are interrelated, such as toughness, stiffness, swelling, or deformability. The improvement of one property usually comes at the cost of another. This thesis aims to develop different hydrogel microstructures and evaluate their potential for load-bearing implants. In particular, the study focuses on (i) designing tough and fatigue resistant hydrogels, (ii) establishing a methodology to control the stiffness and the swelling of hydrogels independently, and (iii) considering processing ease by tailoring each hydrogel precursor viscosity. An extensive parametric study on hydrogels' structure and composition allowed establishing complete property charts for mechanical, swelling, and rheological properties. Seven different hydrogel structures based on poly(ethylene glycol) dimethacrylate were developed: neat, double network, composite, double network composite, granular, hybrid granular, and silk granular hydrogels. The precursors of neat hydrogels had the lowest viscosity. Microgels of similar composition were added to the precursor to adapt and increase its viscosity for unconfined applications. In parallel, adding nano-fibrillated cellulose fibers was effective for increasing toughness. This method was more efficient than creating a double network with alginate. Moreover, fatigue tests revealed that hydrogel composites successfully survive 10 million loading cycles at 20% applied strain. However, it became softer after the first loading cycles and behaved similarly to the Mullins effect. Subsequently, we assessed how cyclic loading affects fracture behavior, distribution of strain fields, and microstructure. The study demonstrated that cyclic loading on hydrogel composites re-arrange the fiber network without seriously deteriorating the mechanical properties. Additionally, we demonstrated that combining composite and microgel approaches, i.e. hybrid granular hydrogels, effectively tailored hydrogels' swelling and viscosity without significantly affecting stiffness, toughness, and deformability. Finally, the microgels were swollen in silk fibroin solution for forming self-reinforced silk granular hydrogels. Those hydrogels exhibited considerably higher stiffness and lower swelling but also reduced elongation performances. We demonstrated that hydrogels' mechanical and physical properties could be effectively controlled with the microstructures and compositions of well-known biomaterials. Subsequently, a hydrogel composite and a silk granular hydrogel, based this time on gelatin hydrogels, were synthesized, validating the potential of studied structures with other hydrogels and microgels. Finally, the analyzed material systems can be combined through a sequential layering, forming hybrid hydrogels, to obtain local or gradient properties addressing specific biomedical applications, soft robotics, sensing applications, or even food packaging.

EPFL2021

Bioengineering stem cell niches in 2D and 3D

Nora Leonardi

Muscle degenerative disorders, such as Duchenne muscular dystrophy, have a profound impact on the quality of life and survival of patients. Transplantation of myoblasts to restore muscle function has been discouraging since these cells die and don't migrate but it has more recently been reported that muscle stem cells, known as satellite cells, have an extraordinary potential to contribute to muscle fiber regeneration, home to their niche and replenish the stem cell pool when injected freshly into damaged muscle. These cells however quickly lose their regenerative potential when cultured in vitro. Adult stem cells are known to be regulated by their microenvironment through a complex mixture of signals including soluble factors, matrix bound proteins, neural input and mechanical properties and the identification of extrinsic factors that can regulate muscle stem cell quiescence and self-renewal has been a focus of research in the Blau lab. Strikingly, recent studies in the Blau lab have shown that muscle stem cells cultured on compliant hydrogels coated with laminin were more viable than those cultured on tissue culture plastic and robustly contributed to muscle regeneration when transplanted into irradiated mouse leg muscles. The aim of this project was to follow up on these findings and to further elucidate the role biophysical and biochemical microenvironmental cues play in the regulation of muscle stem cell fate. Hydrogels have emerged as a popular material to recreate the stem cell niche in vitro due to their biocompatibility, high water content, tissue-like elasticity and diffusive properties and were employed here to fabricate substrates of varying rigidities. The physicochemical properties and tethered protein densities of a range of poyl(ethylene glycol) hydrogels were first characterized to define a suitable set of cell culture substrates. Gel stiffness could be linearly modulated from 2.5 to 45 kPa and the ligand density was found to be in the low femtomolar range. ELISA showed similar protein density on gels of different stiffnesses but immunofluorescence could not fully confirm this. Committed myoblasts were then seeded on these gels and shown to respond to substrate stiffness and ligand density in terms of morphology. Lastly, freshly isolated muscle stem cells were cultured on these gels and on rigid tissue culture plastic and shown to spread more, be more viable and grow more rapidly on stiffer gels as compared to soft ones. Myogenic progression was retrospectively analysed using immunohistochemistry but no differences between culture conditions were observed. Based on the influences of gel rigidity and ligand density observed in vitro, an in vivo assay, the ultimate test of stem cell function, is currently underway.

2009

Bioengineering stem cell niches in 2D and 3D

Nora Leonardi

2009

EPFL2021