A Self‐Sustaining Hydrogels with Autonomous Supply of Nutrients and Bioactive Domains for 3D Cell Culture

Zargarzadeh, Mehrzad; Gomes, Maria C.; Patrício, Sónia G.; Custódio, Catarina A.; Mano, João F.

doi:10.1002/adfm.202214372

Cited by 4 publications

(1 citation statement)

References 71 publications

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“…Zargarzadeh et al. [ 24 ] constructed a photocrosslinked hydrogel based on LAM for cell culture, and the results showed that the degradation products of LAM can provide necessary nutrients to the cells, which, in turn, enhances their viability. LAM is a natural polysaccharide with important research prospects in the biomedical field, but studies on LAM-based hydrogel systems are still scarce.…”

Section: Introductionmentioning

confidence: 99%

Microenvironment Remodeling Self-Healing Hydrogel for Promoting Flap Survival

Ju,

Yang,

Liu

et al. 2024

Biomater Res

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Random flap grafting is a routine procedure used in plastic and reconstructive surgery to repair and reconstruct large tissue defects. Flap necrosis is primarily caused by ischemia–reperfusion injury and inadequate blood supply to the distal flap. Ischemia–reperfusion injury leads to the production of excessive reactive oxygen species, creating a pathological microenvironment that impairs cellular function and angiogenesis. In this study, we developed a microenvironment remodeling self-healing hydrogel [laminarin–chitosan-based hydrogel-loaded extracellular vesicles and ceria nanozymes (LCH@EVs&CNZs)] to improve the flap microenvironment and synergistically promote flap regeneration and survival. The natural self-healing hydrogel (LCH) was created by the oxidation laminarin and carboxymethylated chitosan via a Schiff base reaction. We loaded this hydrogel with CNZs and EVs. CNZs are a class of nanomaterials with enzymatic activity known for their strong scavenging capacity for reactive oxygen species, thus alleviating oxidative stress. EVs are cell-secreted vesicular structures containing thousands of bioactive substances that can promote cell proliferation, migration, differentiation, and angiogenesis. The constructed LCH@EVs&CNZs demonstrated a robust capacity for scavenging excess reactive oxygen species, thereby conferring cellular protection in oxidative stress environments. Moreover, these constructs notably enhance cell migration and angiogenesis. Our results demonstrate that LCH@EVs&CNZs effectively remodel the pathological skin flap microenvironment and marked improve flap survival. This approach introduces a new therapeutic strategy combining microenvironmental remodeling with EV therapy, which holds promise for promoting flap survival.

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Section: Introductionmentioning

confidence: 99%

Microenvironment Remodeling Self-Healing Hydrogel for Promoting Flap Survival

Ju,

Yang,

Liu

et al. 2024

Biomater Res

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Magneto‐Enzymatic Microgels for Precise Hydrogel Sculpturing

Mendes,

Pereira,

Silva

et al. 2024

Advanced Materials

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The inclusion of hollow channels in tissue‐engineered hydrogels is crucial for mimicking the natural physiological conditions and facilitating the delivery of nutrients and oxygen to cells. Although bio‐fabrication techniques provide diverse strategies to create these channels, many require sophisticated equipment and time‐consuming protocols. Herein, collagenase, a degrading agent for methacrylated gelatin hydrogels, and magnetic nanoparticles (MNPs) are combined and processed into enzymatically active spherical structures using a straightforward oil bath emulsion methodology. The generated microgels are then used to microfabricate channels within biomimetic hydrogels via a novel sculpturing approach that relied on the precise coupling of protein‐enzyme pairs (for controlled local degradation) and magnetic actuation (for directional control). Results show that the sculpting velocity can be tailored by adjusting the magnetic field intensity or concentration of MNPs within the microgels. Additionally, varying the magnetic field position or microgel size generated diverse trajectories and channels of different widths. This innovative technology improves the viability of encapsulated cells through enhanced medium transport, outperforming non‐sculpted hydrogels and offering new perspectives for hydrogel vascularization and drug/biomolecule administration. Ultimately, this novel concept can help design fully controlled channels in hydrogels or soft materials, even those with complex tortuosity, in a single wireless top‐down biocompatible step.

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