Spatially‐Encoding Hydrogels With DNA to Control Cell Signaling

Ramani, Namrata; Figg, C. Adrian; Anderson, Alan J.; Winegar, Peter H.; Oh, EunBi; Ebrahimi, Sasha; Mirkin, Chad A.

doi:10.1002/adma.202301086

Cited by 7 publications

(3 citation statements)

References 53 publications

(74 reference statements)

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“…Hydrogels act as cell guidance materials, promoting cartilage formation and repair by modulating pathways, such as RhoA signaling [124]. Formica et al explored an alginate hydrogel that released RhoA inhibitors to enhance chondrocyte differentiation and cartilage formation [14].…”

Section: Regulation Of Cell Signaling Pathwaysmentioning

confidence: 99%

Enhanced Surface Immunomodification of Engineered Hydrogel Materials through Chondrocyte Modulation for the Treatment of Osteoarthritis

Yao,

Huo,

et al. 2024

Coatings

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Osteoarthritis (OA) is characterized by cartilage degeneration and synovial inflammation, with chondrocytes playing a pivotal role in this disease. However, inflammatory mediators, mechanical stress, and oxidative stress can compromise functionality. The occurrence and progression of OA are intrinsically linked to the immune response. Current research on the treatment of OA mainly concentrates on the synergistic application of drugs and tissue engineering. The surface of engineered hydrogel materials can be immunomodified to affect the function of chondrocytes in drug therapy, gene therapy, and cell therapy. Prior studies have concentrated on the drug-loading function of hydrogels but overlooked the immunomodulatory role of chondrocytes. These modifications can inhibit the proliferation and differentiation of chondrocytes, reduce the inflammatory response, and promote cartilage regeneration. The surface immunomodification of engineered hydrogel materials can significantly enhance their efficacy in the treatment of OA. Thus, immunomodulatory tissue engineering has significant potential for treating osteoarthritis.

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Section: Regulation Of Cell Signaling Pathwaysmentioning

confidence: 99%

Enhanced Surface Immunomodification of Engineered Hydrogel Materials through Chondrocyte Modulation for the Treatment of Osteoarthritis

Yao,

Huo,

et al. 2024

Coatings

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“…Cells are known to react to mechanical signals, and hydrogels are capable of simulating the mechanical environments observed in natural tissues. This mimicry allows cells to adhere, migrate, and differentiate, ultimately leading to enhanced tissue regeneration and functional recovery [ 88 , 89 ]. The mechanical properties of hydrogels depend mainly on their composition, cross-linking concentration, cross-linking technique, and polymer concentration [ 90 – 92 ].…”

Section: Hydrogel-based Abdominal Wall Repairmentioning

confidence: 99%

Recent Advances in Functional Hydrogel for Repair of Abdominal Wall Defects: A Review

Liu,

Huang,

et al. 2024

Biomater Res

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The abdominal wall plays a crucial role in safeguarding the internal organs of the body, serving as an essential protective barrier. Defects in the abdominal wall are common due to surgery, infection, or trauma. Complex defects have limited self-healing capacity and require external intervention. Traditional treatments have drawbacks, and biomaterials have not fully achieved the desired outcomes. Hydrogel has emerged as a promising strategy that is extensively studied and applied in promoting tissue regeneration by filling or repairing damaged tissue due to its unique properties. This review summarizes the five prominent properties and advances in using hydrogels to enhance the healing and repair of abdominal wall defects: (a) good biocompatibility with host tissues that reduces adverse reactions and immune responses while supporting cell adhesion migration proliferation; (b) tunable mechanical properties matching those of the abdominal wall that adapt to normal movement deformations while reducing tissue stress, thereby influencing regulating cell behavior tissue regeneration; (c) drug carriers continuously delivering drugs and bioactive molecules to sites optimizing healing processes enhancing tissue regeneration; (d) promotion of cell interactions by simulating hydrated extracellular matrix environments, providing physical support, space, and cues for cell migration, adhesion, and proliferation; (e) easy manipulation and application in surgical procedures, allowing precise placement and close adhesion to the defective abdominal wall, providing mechanical support. Additionally, the advances of hydrogels for repairing defects in the abdominal wall are also mentioned. Finally, an overview is provided on the current obstacles and constraints faced by hydrogels, along with potential prospects in the repair of abdominal wall defects.

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“…Deoxyribonucleic acid (DNA)-based hydrogels represent interesting materials by using DNA as the 3D cross-linking units, taking advantage of its polymeric nature. − “Smart” DNA hydrogels responding to external stimuli, such as pH, ions, light, temperature, chemical or biocatalytic reactions, by transducing output signals, in the form of shape modulation, gel–sol transition, and mechanical switching, attracted intense recent research interest. − By employing noncanonical DNA structures, such as G-quadruplex, i-motif, hairpin, ligand-aptamer, cofactor-dependent DNAzyme, A-motif, or triplexes, , diverse applications have been demonstrated, including sensing, shape memory, loads encapsulation and release, extracellular matrix, electronics, and soft robotics. − …”

Section: Introductionmentioning

confidence: 99%

Oligo-Adenine and Cyanuric Acid Supramolecular DNA-Based Hydrogels Exhibiting Acid-Resistance and Physiological pH-Responsiveness

Hu,

Liu,

et al. 2024

ACS Appl. Mater. Interfaces

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Expanding the functions and applications of DNA by integrating noncanonical bases and structures into biopolymers is a continuous scientific effort. An adenine-rich strand (A-strand) is introduced as functional scaffold revealing, in the presence of the low-molecular-weight cofactor cyanuric acid (CA, pK a 6.9), supramolecular hydrogel-forming efficacies demonstrating multiple pH-responsiveness. At pH 1.2, the A-strand transforms into a parallel A-motif duplex hydrogel cross-linked by AH+-H+A units due to the protonation of adenine (pK a 3.5). At pH 5.2, and in the presence of coadded CA, a helicene-like configuration is formed between adenine and protonated CA, generating a parallel A-CA triplex cross-linked hydrogel. At pH 8.0, the hydrogel undergoes transition into a liquid state by deprotonation of CA cofactor units and disassembly of A-CA triplex into its constituent components. Density functional theory calculations and molecular dynamics simulations, supporting the structural reconfigurations of A-strand in the presence of CA, are performed. The sequential pH-stimulated hydrogel states are rheometrically characterized. The hydrogel framework is loaded with fluorescein-labeled insulin, and the pH-stimulated release of insulin from the hydrogel across the pH barriers present in the gastrointestinal tract is demonstrated. The results provide principles for future application of the hydrogel for oral insulin administration for diabetes.

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Spatially‐Encoding Hydrogels With DNA to Control Cell Signaling

Cited by 7 publications

References 53 publications

Enhanced Surface Immunomodification of Engineered Hydrogel Materials through Chondrocyte Modulation for the Treatment of Osteoarthritis

Enhanced Surface Immunomodification of Engineered Hydrogel Materials through Chondrocyte Modulation for the Treatment of Osteoarthritis

Recent Advances in Functional Hydrogel for Repair of Abdominal Wall Defects: A Review

Oligo-Adenine and Cyanuric Acid Supramolecular DNA-Based Hydrogels Exhibiting Acid-Resistance and Physiological pH-Responsiveness

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