Adaptable hydrogel with reversible linkages for regenerative medicine: Dynamic mechanical microenvironment for cells

Tong, Zongrui; Jin, Lai; Oliveira, Joaquím M.; Reis, Rui L.; Zhong, Qi; Mao, Zhengwei; Gao, Changyou

doi:10.1016/j.bioactmat.2020.10.029

Cited by 98 publications

(81 citation statements)

References 152 publications

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“…In the future, using different mechanically sensitive cells (e.g., cardiomyocytes) or further increasing the structural anisotropy and internal strain represent possible ways to examine the impact of the 4D process on cell behaviors. Nevertheless, additional engineering of the materials, such as modification with cell adhesive ligands (e.g., RGD peptide motif) [ [64] , [65] , [66] ], tuning matrix physical properties [ 67 ], facilitation of cell-cell interactions [ 54 ] and/or controlled delivery of bioactive factors [ [68] , [69] , [70] , [71] ], may also be further explored to promote survival of diverse encapsulated cell population and enhance cell functioning.…”

Section: Resultsmentioning

confidence: 99%

4D biofabrication via instantly generated graded hydrogel scaffolds

Ding

Lee

Ayyagari

et al. 2022

Bioactive Materials

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Formation of graded biomaterials to render shape-morphing scaffolds for 4D biofabrication holds great promise in fabrication of complex structures and the recapitulation of critical dynamics for tissue/organ regeneration. Here we describe a facile generation of an adjustable and robust gradient using a single- or multi-material one-step fabrication strategy for 4D biofabrication. By simply photocrosslinking a mixed solution of a photocrosslinkable polymer macromer, photoinitiator (PI), UV absorber and live cells, a cell-laden gradient hydrogel with pre-programmable deformation can be generated. Gradient formation was demonstrated in various polymers including poly(ethylene glycol) (PEG), alginate, and gelatin derivatives using various UV absorbers that present overlap in UV spectrum with that of the PI UV absorbance spectrum. Moreover, this simple and effective method was used as a universal platform to integrate with other hydrogel-engineering techniques such as photomask-aided microfabrication, photo-patterning, ion-transfer printing, and 3D bioprinting to fabricate more advanced cell-laden scaffold structures. Lastly, proof-of-concept 4D tissue engineering was demonstrated in a study of 4D bone-like tissue formation. The strategy's simplicity along with its versatility paves a new way in solving the hurdle of achieving temporal shape changes in cell-laden single-component hydrogel scaffolds and may expedite the development of 4D biofabricated constructs for biological applications.

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Section: Resultsmentioning

confidence: 99%

4D biofabrication via instantly generated graded hydrogel scaffolds

Ding

Lee

Ayyagari

et al. 2022

Bioactive Materials

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“…, tendons, skin, fibrous tissues, nerves, among others . ) restoration and regeneration, has been extensively exploited and rapidly developed in regenerative medicine [ 305 , 306 ]. Bioinspired materials play a pivotal role in providing a template and extracellular environment to support regenerative cells and promote tissue regeneration [ 307 , 308 ].…”

Section: Biomedical Applications Of Pll-based Polymersmentioning

confidence: 99%

Poly(α-l-lysine)-based nanomaterials for versatile biomedical applications: Current advances and perspectives

Zheng

Pan

Zhang

et al. 2021

Bioactive Materials

123

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Poly(α- l -lysine) (PLL) is a class of water-soluble, cationic biopolymer composed of α- l -lysine structural units. The previous decade witnessed tremendous progress in the synthesis and biomedical applications of PLL and its composites. PLL-based polymers and copolymers, till date, have been extensively explored in the contexts such as antibacterial agents, gene/drug/protein delivery systems, bio-sensing, bio-imaging, and tissue engineering. This review aims to summarize the recent advances in PLL-based nanomaterials in these biomedical fields over the last decade. The review first describes the synthesis of PLL and its derivatives, followed by the main text of their recent biomedical applications and translational studies. Finally, the challenges and perspectives of PLL-based nanomaterials in biomedical fields are addressed.

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“…The flexibility and permeability possessed by self-healing hydrogels enhances nutrient exchange and increases the viability of cells. Additionally, they provide the chemical and physical dynamism required to control cell growth, behavior, and fate [62,170] and mitigate the shortcomings of traditional hydrogels. Figure 11 highlights the composition, architecture, and physical properties of the ECM and the factors that contribute to cell fate and ECM remodeling.…”

Section: Effect Of Self-healing Properties On Cellsmentioning

confidence: 99%

Self-Healing Hydrogels: Preparation, Mechanism and Advancement in Biomedical Applications

Shyam

Palaniappan

et al. 2021

Polymers

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Polymeric hydrogels are widely explored materials for biomedical applications. However, they have inherent limitations like poor resistance to stimuli and low mechanical strength. This drawback of hydrogels gave rise to ‘‘smart self-healing hydrogels’’ which autonomously repair themselves when ruptured or traumatized. It is superior in terms of durability and stability due to its capacity to reform its shape, injectability, and stretchability thereby regaining back the original mechanical property. This review focuses on various self-healing mechanisms (covalent and non-covalent interactions) of these hydrogels, methods used to evaluate their self-healing properties, and their applications in wound healing, drug delivery, cell encapsulation, and tissue engineering systems. Furthermore, composite materials are used to enhance the hydrogel’s mechanical properties. Hence, findings of research with various composite materials are briefly discussed in order to emphasize the healing capacity of such hydrogels. Additionally, various methods to evaluate the self-healing properties of hydrogels and their recent advancements towards 3D bioprinting are also reviewed. The review is concluded by proposing several pertinent challenges encountered at present as well as some prominent future perspectives.

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Adaptable hydrogel with reversible linkages for regenerative medicine: Dynamic mechanical microenvironment for cells

Cited by 98 publications

References 152 publications

4D biofabrication via instantly generated graded hydrogel scaffolds

4D biofabrication via instantly generated graded hydrogel scaffolds

Poly(α-l-lysine)-based nanomaterials for versatile biomedical applications: Current advances and perspectives

Self-Healing Hydrogels: Preparation, Mechanism and Advancement in Biomedical Applications

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