Graphene oxide encapsulated forsterite scaffolds to improve mechanical properties and antibacterial behavior

Abstract: It is very desirable to have good antibacterial properties and mechanical properties at the same time for bone scaffolds. Graphene oxide (GO) can increase the mechanical properties and antibacterial performance, while forsterite (Mg2SiO4) as the matrix can increase forsterite/GO scaffolds' biological activity for bone tissue engineering. Interconnected porous forsterite scaffolds were developed by space holder processes for bone tissue engineering in this research. The forsterite/GO scaffolds had a porosity of… Show more

“…Mainly, carbon nanomaterials can increase the mechanical characteristic of composites due to the following reasons: (1) easy chemical functionalization, 58 (2) interaction of functional groups such as hydroxyl, carboxyl, ketone, and epoxy in various types of carbon nanomaterials with other functional groups in composite components, 59 (3) formation of strong p-p interaction between carbon sheets and other composite components, 60 and (4) formation of hydrogen bonding between the carboxyl and carbonyl groups of carbon nanomaterials and hydroxyl groups of other components in composites. 61 According to the information provided in the literature, carbon nanostructures and the aforementioned interactions enhance the mechanical properties including compressive strength, 62 tensile strength, 63 toughness, 64 Young's modulus, 65 and elastic modulus 66 of composites. The effective mechanical properties of carbon nanomaterials in the composites facilitate their use in several biomedical applications, especially tissue engineering.…”

“…According to the information provided in the literature, carbon nanostructures and the aforementioned interactions enhance the mechanical properties including compressive strength, 62 tensile strength, 63 toughness, 64 Young's modulus, 65 and elastic modulus 66 of composites. The effective mechanical properties of carbon nanomaterials in the composites facilitate their use in several biomedical applications, especially tissue engineering.…”

Effects of mechanical properties of carbon-based nanocomposites on scaffolds for tissue engineering applications: a comprehensive review

“…Mainly, carbon nanomaterials can increase the mechanical characteristic of composites due to the following reasons: (1) easy chemical functionalization, 58 (2) interaction of functional groups such as hydroxyl, carboxyl, ketone, and epoxy in various types of carbon nanomaterials with other functional groups in composite components, 59 (3) formation of strong p-p interaction between carbon sheets and other composite components, 60 and (4) formation of hydrogen bonding between the carboxyl and carbonyl groups of carbon nanomaterials and hydroxyl groups of other components in composites. 61 According to the information provided in the literature, carbon nanostructures and the aforementioned interactions enhance the mechanical properties including compressive strength, 62 tensile strength, 63 toughness, 64 Young's modulus, 65 and elastic modulus 66 of composites. The effective mechanical properties of carbon nanomaterials in the composites facilitate their use in several biomedical applications, especially tissue engineering.…”

“…According to the information provided in the literature, carbon nanostructures and the aforementioned interactions enhance the mechanical properties including compressive strength, 62 tensile strength, 63 toughness, 64 Young's modulus, 65 and elastic modulus 66 of composites. The effective mechanical properties of carbon nanomaterials in the composites facilitate their use in several biomedical applications, especially tissue engineering.…”

Effects of mechanical properties of carbon-based nanocomposites on scaffolds for tissue engineering applications: a comprehensive review

“…This field combines various strategies, including cell-based therapies, scaffolds, and bioactive molecules, to achieve synergistic effects and enhance tissue regeneration outcomes. By utilizing these approaches, soft tissue engineering seeks to promote the regeneration of soft tissues like skin, blood vessels, and muscles, ultimately improving the quality of life for patients with tissue damage or loss. , Soft tissue engineering allows for the development of personalized treatments tailored to individual patients, considering factors such as tissue defects, patient-specific characteristics, and functional requirements. , In addition, the use of biomaterial scaffolds provides structural support, facilitates cell infiltration, and guides tissue regeneration. , These scaffolds can be designed to mimic the native tissue architecture, providing a favorable environment for cell adhesion, proliferation, and differentiation. − Notably, strategies applied for soft TRE should enable the controlled release of bioactive factors, such as growth factors or cytokines, to promote tissue regeneration. This localized delivery enhances therapeutic efficacy while minimizing potential side effects .…”

Multifunctional MXene-Based Platforms for Soft and Bone Tissue Regeneration and Engineering

“…1% GO encapsulated forsterite (Mg 2 SiO 4 ) scaffolds recently showed a porosity of 76%–78% with pore size of 300–450 ​μm, good cell biocompatibility, enhanced cell proliferation and potent antibacterial performance for bone tissue engineering [ 150 ].…”

Scaffolds in the microbial resistant era: Fabrication, materials, properties and tissue engineering applications