In Situ Forming, Silanized Hyaluronic Acid Hydrogels with Fine Control Over Mechanical Properties and In Vivo Degradation for Tissue Engineering Applications

Flegeau, Killian; Toquet, Claire; Réthoré, Gildas; d’Arros, Cyril; Messager, Lea; Halgand, Boris; Dupont, Davy; Autrusseau, Florent; Lesoeur, Julie; Véziers, Joëlle; Bordat, Patrice; Bresin, Anthony; Guicheux, Jérôme; Delplace, Vianney; Gautier, H; Weiss, Pierre

doi:10.1002/adhm.202000981

Cited by 16 publications

(18 citation statements)

References 70 publications

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“…Silane serves as a covalent crosslinker and forms covalent bonds between the polymers, maintaining the stability of the overall hydrogel network. [ 27 ] AgNPs are incorporated to introduce the antibacterial activity to the hydrogel. Meanwhile, the carboxyl groups on the polymer chain ionically crosslink with Ca 2+ to form a double‐crosslinking matrix (Figure S1, Supporting Information).…”

Section: Resultsmentioning

confidence: 99%

A Carboxymethyl Chitosan‐Based Double‐Crosslinking Hydrogel with Enhanced Antibacterial Properties for Accelerated Wound Healing

Huang

Sun

et al. 2022

Macro Materials & Eng

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Here, a novel double-crosslinked hydrogel dressing with enhanced antibacterial and anti-inflammatory activities is reported. Carboxymethyl chitosan is crosslinked with silane and Ca 2+ to form a double-crosslinked hydrogel, and silver nanoparticles are loaded to introduce antibacterial properties to the hydrogel. The covalent crosslinking preserves the integrity of the hydrogel matrix, while the ionic crosslinking dissipates the energy under deformation. It combines high stretchability, toughness, tissue adhesion, and antimicrobial function. This hydrogel exhibits excellent cytocompatibility and hemocompatibility. Moreover, in vitro and in vivo investigations demonstrate its efficacy in accelerating bacterial-infected wound healing. Given its excellent cytocompatibility and mechanical properties, this hydrogel is anticipated to be widely used in bacteria-associated wound management.

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Section: Resultsmentioning

confidence: 99%

A Carboxymethyl Chitosan‐Based Double‐Crosslinking Hydrogel with Enhanced Antibacterial Properties for Accelerated Wound Healing

Huang

Sun

et al. 2022

Macro Materials & Eng

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“…In closing, the TEA set-up has the potential to be adapted for in situ applications during surgical procedures, where gel components containing cells and/or biofactors can be injected directly into a deteriorated organ site and organized via acoustic fields in the required pattern. Injectable smart materials with tunable mechanical properties [ 72 , 73 ] and non-invasive technologies, such as TEA, are of critical importance for this indispensable advancement in personalized medicine.…”

Section: Discussionmentioning

confidence: 99%

A Tissue Engineering Acoustophoretic (TEA) Set-up for the Enhanced Osteogenic Differentiation of Murine Mesenchymal Stromal Cells (mMSCs)

Zhang

Beilfuss

Zabaryło

et al. 2022

IJMS

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Quickly developing precision medicine and patient-oriented treatment strategies urgently require novel technological solutions. The randomly cell-populated scaffolds usually used for tissue engineering often fail to mimic the highly anisotropic characteristics of native tissue. In this work, an ultrasound standing-wave-based tissue engineering acoustophoretic (TEA) set-up was developed to organize murine mesenchymal stromal cells (mMSCs) in an in situ polymerizing 3-D fibrin hydrogel. The resultant constructs, consisting of 17 cell layers spaced at 300 µm, were obtained by continuous wave ultrasound applied at a 2.5 MHz frequency. The patterned mMSCs preserved the structured behavior within 10 days of culturing in osteogenic conditions. Cell viability was moderately increased 1 day after the patterning; it subdued and evened out, with the cells randomly encapsulated in hydrogels, within 21 days of culturing. Cells in the structured hydrogels exhibited enhanced expression of certain osteogenic markers, i.e., Runt-related transcription factor 2 (RUNX2), osterix (Osx) transcription factor, collagen-1 alpha1 (COL1A1), osteopontin (OPN), osteocalcin (OCN), and osteonectin (ON), as well as of certain cell-cycle-progression-associated genes, i.e., Cyclin D1, cysteine-rich angiogenic inducer 61 (CYR61), and anillin (ANLN), when cultured with osteogenic supplements and, for ANLN, also in the expansion media. Additionally, OPN expression was also augmented on day 5 in the patterned gels cultured without the osteoinductive media, suggesting the pro-osteogenic influence of the patterned cell organization. The TEA set-up proposes a novel method for non-invasively organizing cells in a 3-D environment, potentially enhancing the regenerative properties of the designed anisotropic constructs for bone healing.

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“…HA naturally acts as a signaling molecule for cell migration and proliferation ( Lee et al, 2021 ), owing to its extensive use in hydrogel formulation. In situ -forming, silanized hyaluronic acid hydrogels with tunable mechanical properties were able to sustain cell viabilities of over 80% after 7 days of culture ( Flegeau et al, 2020 ).…”

Section: Strategies Developed For Improving Bioink’s Printabilitymentioning

confidence: 99%

Bioink Formulation and Machine Learning-Empowered Bioprinting Optimization

Freeman

Calabrò

Williams

et al. 2022

Front. Bioeng. Biotechnol.

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Bioprinting enables the fabrication of complex, heterogeneous tissues through robotically-controlled placement of cells and biomaterials. It has been rapidly developing into a powerful and versatile tool for tissue engineering. Recent advances in bioprinting modalities and biofabrication strategies as well as new materials and chemistries have led to improved mimicry and development of physiologically relevant tissue architectures constituted with multiple cell types and heterogeneous spatial material properties. Machine learning (ML) has been applied to accelerate these processes. It is a new paradigm for bioprinting. In this review, we explore current trends in bioink formulation and how ML has been used to accelerate optimization and enable real-time error detection as well as to reduce the iterative steps necessary for bioink formulation. We examined how rheometric properties, including shear storage, loss moduli, viscosity, shear-thinning property of biomaterials affect the printability of a bioink. Furthermore, we scrutinized the interplays between yield shear stress and the printability of a bioink. Moreover, we systematically surveyed the application of ML in precision in situ surgical site bioprinting, closed-loop AI printing, and post-printing optimization.

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In Situ Forming, Silanized Hyaluronic Acid Hydrogels with Fine Control Over Mechanical Properties and In Vivo Degradation for Tissue Engineering Applications

Cited by 16 publications

References 70 publications

A Carboxymethyl Chitosan‐Based Double‐Crosslinking Hydrogel with Enhanced Antibacterial Properties for Accelerated Wound Healing

A Carboxymethyl Chitosan‐Based Double‐Crosslinking Hydrogel with Enhanced Antibacterial Properties for Accelerated Wound Healing

A Tissue Engineering Acoustophoretic (TEA) Set-up for the Enhanced Osteogenic Differentiation of Murine Mesenchymal Stromal Cells (mMSCs)

Bioink Formulation and Machine Learning-Empowered Bioprinting Optimization

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