Mineralization of gellan gum hydrogels with calcium and magnesium carbonates by alternate soaking in solutions of calcium/magnesium and carbonate ion solutions

Lopez‐Heredia, Marco A.; Łapa, Agata; Reczyńska, Katarzyna; Pietryga, Krzysztof; Balcaen, Lieve; Mendes, Ana Carina Loureiro; Schaubroeck, David; Voort, Pascal Van Der; Dokupil, Agnieszka; Plis, Agnieszka; Stevens, Christian V.; Parakhonskiy, Bogdan; Samal, Sangram Keshari; Vanhaecke, Frank; Chai, Feng; Chronakis, Ioannis S.; Blanchemain, Nicolas; Pamuła, Elżbieta; Skirtach, André G.; Douglas, Timothy E.L.

doi:10.1002/term.2675

Cited by 20 publications

(11 citation statements)

References 34 publications

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“…[ 56 ] Together with the in situ gelation ability of GG hydrogels, those properties have been supporting their exploitation for different regenerative medicine applications. [ 57 ] Either acellular or cellular strategies were successfully proposed for drug delivery, [ 58 ] bone, [ 59–61 ] and nerves [ 62 ] repair. However, cell adhesion to commonly assembled GG is practically absent.…”

Section: Introductionmentioning

confidence: 99%

“…[ 56,63,64 ] Cell adhesion features to GG hydrogels have been provided only by the combination with gelatin, [ 65 ] GG modification with a GRGDS peptide [ 66 ] sequence and mineralization with calcium and magnesium carbonates. [ 60,67 ] Also, there are different approaches for enhancing cell adhesion properties, including hybrid materials, [ 28,29 ] where inorganic components (often nanoparticles) directly stimulate the cell growth by incorporation of such biomolecules as alkaline phosphatase. [ 68,69 ] Nanoparticles have been recognized for affecting the polymeric structures, [ 70,71 ] so controlled nanoparticle adsorption [ 72 ] at biointerfaces has been shown, on the one hand, to serve as activation centers, [ 73 ] while, on the other hand, to promote cell adhesion.…”

Section: Introductionmentioning

confidence: 99%

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Nanofibrillar Hydrogels by Temperature Driven Self‐Assembly: New Structures for Cell Growth and Their Biological and Medical Implications

Abalymov

Santos

Meeren

et al. 2021

Adv Materials Inter

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Nanofibrillar structures are of importance in biomedicine, including lung, cardiovascular, liver, skin, neuroscience research, and tissue engineering. Developing advanced materials and interfaces should contribute to uncovering the mechanisms of diseases aiming to find cure. The similarity between the extracellular matrix (ECM) of soft tissue and hydrogels, characterized by a high water‐content viscoelastic polymeric fiber, has stimulated the development of hydrogels for biomedical applications. However, most hydrogels have a meshy structure resulting in poor cell adhesion properties. Here, fabrication of gellan gum (GG) hydrogels arranged by thermally driven self‐assembly into a network of nanofibers is reported. Mechanical properties of such nanofibrillar hydrogels are analyzed on micro‐ and macroscales. As a result, and in sharp contrast to commonly produced meshy GG hydrogels, the nanofiber‐based hydrogels facilitate the adherence and lead to proliferation of cells. This is assigned to microstructural rearrangements characterized by a changing density and pore size decrease, accompanied with a lower water content. Cell growth on such nanofibrillar structures is investigated for osteoblasts, which are chosen as a model system. The developed nanofibrous interfaces in this study are envisioned to be applicable for growing various types of cells and they should contribute to better understanding cell interactions with ECM.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nanofibrillar Hydrogels by Temperature Driven Self‐Assembly: New Structures for Cell Growth and Their Biological and Medical Implications

Abalymov

Santos

Meeren

et al. 2021

Adv Materials Inter

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“…Differences between the structures of WPI hydrogels and GG hydrogels may influence the type of mineral formed. The concentration of polymer in WPI hydrogels in this study (50% (w/v)) is much higher than in the GG hydrogels used in previous works (0.7% (w/v)) [10,14,15]. A higher concentration of polymer would lead to smaller pores in the polymer network.…”

Section: Discussionmentioning

confidence: 67%

“…During enzymatic mineralization of hydrogels with CaCO 3 , magnesium ions can be added to the mineralization medium which may lead to an increase in cell number [13,14]. In previous work, Gellan Gum (GG) hydrogels have been mineralized with CaCO 3 and/or calcium magnesium carbonate by incorporation of the enzyme urease into the hydrogel network followed by incubation in a solution containing the enzyme substrate, urea, and calcium and magnesium ions [14,15].…”

Section: Introductionmentioning

confidence: 99%

Marine-Inspired Enzymatic Mineralization of Dairy-Derived Whey Protein Isolate (WPI) Hydrogels for Bone Tissue Regeneration

et al. 2020

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Whey protein isolate (WPI) is a by-product from the production of cheese and Greek yoghurt comprising β-lactoglobulin (β-lg) (75%). Hydrogels can be produced from WPI solutions through heating; hydrogels can be sterilized by autoclaving. WPI hydrogels have shown cytocompatibility and ability to enhance proliferation and osteogenic differentiation of bone-forming cells. Hence, they have promise in the area of bone tissue regeneration. In contrast to commonly used ceramic minerals for bone regeneration, a major advantage of hydrogels is the ease of their modification by incorporating biologically active substances such as enzymes. Calcium carbonate (CaCO3) is the main inorganic component of the exoskeletons of marine invertebrates. Two polymorphs of CaCO3, calcite and aragonite, have shown the ability to promote bone regeneration. Other authors have reported that the addition of magnesium to inorganic phases has a beneficial effect on bone-forming cell growth. In this study, we employed a biomimetic, marine-inspired approach to mineralize WPI hydrogels with an inorganic phase consisting of CaCO3 (mainly calcite) and CaCO3 enriched with magnesium using the calcifying enzyme urease. The novelty of this study lies in both the enzymatic mineralization of WPI hydrogels and enrichment of the mineral with magnesium. Calcium was incorporated into the mineral formed to a greater extent than magnesium. Increasing the concentration of magnesium in the mineralization medium led to a reduction in the amount and crystallinity of the mineral formed. Biological studies revealed that mineralized and unmineralized hydrogels were not cytotoxic and promoted cell viability to comparable extents (approximately 74% of standard tissue culture polystyrene). The presence of magnesium in the mineral formed had no adverse effect on cell viability. In short, WPI hydrogels, both unmineralized and mineralized with CaCO3 and magnesium-enriched CaCO3, show potential as biomaterials for bone regeneration.

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“…Gellan gum hydrogels allow as well for mineralized by incubation of alkaline phosphatase in mineralization media containing calcium and/or magnesium glycerophosphate for applications in bone regeneration . Mineral formation was confirmed by various techniques, Ca being incorporated into mineral to a greater extent than Mg, but samples with Mg incorporated into mineral, enhanced osteoblast attachment and proliferation.…”

Section: Gellan Gummentioning

confidence: 99%

Advancement in the Biomedical Applications of the (Nano)gel Structures Based on Particular Polysaccharides

Chiriac¹,

Ghilan²,

Neamţu³

et al. 2019

Macromolecular Bioscience

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/mabi.201900187. Nanogels (Nano)gels from macromolecular compounds-natural, synthetic, or a combination thereof, suitable crosslinkers-and conferred characteristicssuch as degradability, size, charge, amphiphilicity, responsiveness, and softness-are capable of responding to the challenges imposed by bioengineering applications. Polysaccharide-based gels have received particular attention in this field. This review addresses recent advancement in the use of (nano)gel structures prepared only from compounds based on gellan gum, heparin, chondroitin sulfate, carrageenan, guar gum, galactose, or agarose, which represent an important part of the special class of natural polymers, the polysaccharides. Also, future trends are taken into discussion regarding the (nano)gels' use in biomedical applications such as biomimetics, biosensors, artificial muscles, and chemical separations in relation with their ability to be used as a vehicle for various biomolecules due to their physicochemical properties, biocompatibility, and biodegradability.

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Mineralization of gellan gum hydrogels with calcium and magnesium carbonates by alternate soaking in solutions of calcium/magnesium and carbonate ion solutions

Cited by 20 publications

References 34 publications

Nanofibrillar Hydrogels by Temperature Driven Self‐Assembly: New Structures for Cell Growth and Their Biological and Medical Implications

Nanofibrillar Hydrogels by Temperature Driven Self‐Assembly: New Structures for Cell Growth and Their Biological and Medical Implications

Marine-Inspired Enzymatic Mineralization of Dairy-Derived Whey Protein Isolate (WPI) Hydrogels for Bone Tissue Regeneration

Advancement in the Biomedical Applications of the (Nano)gel Structures Based on Particular Polysaccharides

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