Effect on Rheological Properties and 3D Printability of Biphasic Calcium Phosphate Microporous Particles in Hydrocolloid-Based Hydrogels

Herrada‐Manchón, Helena; Rodríguez-González, David; Fernández, Manuel; Kucko, Nathan W.; Groot, Florénce Barrère-de; Aguilar, Enrique

doi:10.3390/gels8010028

Cited by 20 publications

(13 citation statements)

References 51 publications

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“…LVER indicates the range in which an oscillatory rheology test can be performed without destroying the structure of the sample, 16 which means that in the LVER region, the G' and G" are parallel to each other and are independent to the applied strain. As soon as the G' and G" crosses each other the hydrogel starts to behave like a liquid material.…”

Section: Resultsmentioning

confidence: 99%

Self‐healing mineralized hydrogel scaffolds for stretch‐triggered dye release

Palit,

Suryavanshi,

Banerjee

2024

Polymers for Advanced Techs

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Hydrogels, with self‐healing properties that can self‐repair spontaneously when subjected to mechanical stress, are gaining popularity in the biomedical field. Numerous attempts have been made to create distinctive hydrogels with self‐healing properties, along with stimuli‐responsiveness and biocompatibility. Several techniques exist for fabricating hydrogels, including physical and chemical crosslinking via the creation of covalent bonds, and so on. Here, we prepared self‐healing, stimuli‐responsive, mineralized hydrogel by simply dissolving Kollidon 90‐F, sodium chloride (NaCl), and potassium carbonate (K2CO3) in an aqueous solution. The dissociated CO32− replaces the water molecules from the Kollidon 90‐F polymer backbone and facilitates the cross‐linking of the polymer chain, resulting in hydrogel formation. In addition, the in‐situ produced sodium carbonate (Na2CO3) strengthens the hydrogel network. We optimized the mineralized hydrogels by taking various metal salts and different concentrations of K2CO3. The optimized hydrogel showed good stability over a period of time, was able to maintain viscoelastic properties, possessed good self‐healing ability, and showed a shape retention ability. The shear‐thinning property demonstrated by the optimized hydrogel could open a ray of hope in the bioprinting or 3D printing industry. Further, the stretch‐responsive release of dye from the Self‐healing mineralized hydrogel (SHMH) matrix confirms the mechanoresponsive behavior of the hydrogel. Overall, the findings could be utilized in the future to fabricate a stable drug delivery system that can autonomously release the drug molecules when stretched by daily processes such as joint movements.

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Section: Resultsmentioning

confidence: 99%

Self‐healing mineralized hydrogel scaffolds for stretch‐triggered dye release

Palit,

Suryavanshi,

Banerjee

2024

Polymers for Advanced Techs

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“…With cellulose-based feedstocks, 3D printing proceeds via the creation of solutions, suspensions, and pastes with carefully controlled rheological properties to enable material extrusion. The shear thinning (specifically, thixotropic) behavior of these cellulosebased materials, and bioinks in general, as they are extruded and subsequently solidified, is of particular importance [51][52][53]. As material is extruded from a nozzle during 3D printing, it experiences a shear stress determined by nozzle size, printing pressure, and the viscosity of the printing feedstock [54].…”

Section: Printing Methodsmentioning

confidence: 99%

Materials and Methods for All-Cellulose 3D Printing in Sustainable Additive Manufacturing

Albelo,

Raineri,

Salmon

2024

Sustainable Chemistry

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Additive manufacturing, commonly referred to as 3D printing, is an exciting and versatile manufacturing technology that has gained traction and interest in both academic and industrial settings. Polymeric materials are essential components in a majority of the feedstocks used across the various 3D printing technologies. As the environmental ramifications of sole or primary reliance on petrochemicals as a resource for industrial polymers continue to manifest themselves on a global scale, a transition to more sustainable bioderived alternatives could offer solutions. In particular, cellulose is promising due to its global abundance, biodegradability, excellent thermal and mechanical properties, and ability to be chemically modified to suit various applications. Traditionally, native cellulose was incorporated in additive manufacturing applications only as a substrate, filler, or reinforcement for other materials because it does not melt or easily dissolve. Now, the exploration of all-cellulose 3D printed materials is invigorated by new liquid processing strategies involving liquid-like slurries, nanocolloids, and advances in direct cellulose solvents that highlight the versatility and desirable properties of this abundant biorenewable photosynthetic feedstock. This review discusses the progress of all-cellulose 3D printing approaches and the associated challenges, with the purpose of promoting future research and development of this important technology for a more sustainable industrial future.

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“…The extent of thixotropy is intricately linked to both the duration of applied shear stress, and the magnitude of the shear rate. 75 Both metallo-hydrogels and non-metallo-hydrogels exhibit remarkable thixotropic properties based on observations of their rapid recovery to the gel-like state. Upon the stopping of the shear force, the storage modulus (G′) of the P2 hydrogel swiftly increased by more than three orders of magnitude within a few seconds.…”

Section: Figmentioning

confidence: 99%

Tunable metallo-hydrogels: Mechanical properties and characterization of stimuli responsive self-assembling peptide hydrogels

Tialiou,

Serpell,

et al. 2024

Preprint

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Supramolecular self-assembly is employed in this study to design short amphiphilic peptides with specific binding affinity for Zn(II). Two selectively modified peptides (Ac-LIVKHH-NH2, P1 & Fmoc-LIVKHH-NH2, P2) were synthesized using standard Fmoc-/Boc- solid-phase peptide synthesis. When these water-soluble peptides are combined with Zn(II) salt solution, they encapsulate large volumes of water to form metallo-hydrogels. The Zn(II) responsiveness in metallo-hydrogels was investigated in buffer or water (pH 7) with or without Zn(II) salts. The afforded supramolecular architectures (metallo-hydrogels) were characterized by circular dichroism and their micro- and nanostructure with scanning electron microscopy (SEM) and transmission electron microscopy (TEM), respectively. Measurements of rheology and thixotropy were conducted to assess the gelation behavior, the viscoelastic character and the mechanical properties of metallo-hydrogels. We found that Zn(II) significantly influences hydrogel formation, leading to improved mechanical properties. The resulting hydrogels show remarkable thixotropic behavior, indicating their potential in 3D printing and as injectable carriers. Such hydrogels can be also used as primary wound dressings, and their antibacterial activity can be further explored. This research work provides valuable insights into the zinc-responsive behavior of the aforementioned peptides, establishing a foundation for their prospective applications in biomaterials and materials science.

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Effect on Rheological Properties and 3D Printability of Biphasic Calcium Phosphate Microporous Particles in Hydrocolloid-Based Hydrogels

Cited by 20 publications

References 51 publications

Self‐healing mineralized hydrogel scaffolds for stretch‐triggered dye release

Self‐healing mineralized hydrogel scaffolds for stretch‐triggered dye release

Materials and Methods for All-Cellulose 3D Printing in Sustainable Additive Manufacturing

Tunable metallo-hydrogels: Mechanical properties and characterization of stimuli responsive self-assembling peptide hydrogels

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