Recent Advances in Potential Biomedical Applications of MXene‐Based Hydrogels DOI
Ali Hamzehlouy, Masoud Tavakoli Dare,

Farangis Shahi

et al.

Polymers for Advanced Technologies, Journal Year: 2024, Volume and Issue: 35(12)

Published: Nov. 29, 2024

ABSTRACT MXene‐based hydrogels represent a significant advancement in biomedical material science, leveraging the unique properties of 2D MXenes and versatile functionality hydrogels. This review discusses recent developments integration into hydrogel matrices, focusing on their applications such as wound healing, drug delivery, antimicrobial activity, tissue engineering, biosensing. MXenes, due to remarkable electrical conductivity, mechanical robustness, tunable surface chemistry, enhance properties, responsiveness environmental stimuli. Specifically, have shown great promise accelerating healing through photothermal effects, delivering drugs controlled manner, serving antibacterial agents. Their also enables targeted cancer therapies, including chemodynamic facilitated by high conductivity properties. Despite promising progress, challenges ensuring biocompatibility optimizing synthesis for large‐scale production remain. aims provide comprehensive overview current state applications, highlighting ongoing advancements potential future directions these multifunctional materials.

Language: Английский

Polymer and Nanocomposite Fillers as Advanced Materials in Biomedical Applications DOI Creative Commons
Angeline Julius,

Suresh Malakondaiah,

Raghu Babu Pothireddy

et al.

Nano Trends, Journal Year: 2025, Volume and Issue: unknown, P. 100087 - 100087

Published: Feb. 1, 2025

Language: Английский

Citations

2
A machine learning and data-oriented quest to screen the degree of long-range order/disorder in polymeric materials DOI
Cihat Güleryüz, Sajjad Hussain Sumrra,

Abrar U. Hassan

et al.

Materials Today Communications, Journal Year: 2025, Volume and Issue: unknown, P. 111624 - 111624

Published: Jan. 1, 2025

Language: Английский

Citations

1
Optimizing Electrospun PVA Fibers with MXene Integration for Biomedical Applications DOI Creative Commons
Nergis Zeynep Renkler, Zaheer Ud Din Babar, Mario Barra

et al.

Macromolecular Materials and Engineering, Journal Year: 2025, Volume and Issue: unknown

Published: March 13, 2025

Abstract MXene‐based materials have gained attention in the biomedical field due to their promising biocompatibility, improved mechanical strength, and conductivity. In this study, focus is on optimizing MXene‐incorporated electrospun fibers subsequent characterizations assess potential for applications. Polyvinyl alcohol (PVA) used as appropriate matrix material process parameters are finetuned ensure effective incorporation of MXene. XRD spectroscopic analysis confirm successful synthesis integration MXenes into nanofibers. Morphological shows that MXene led formation sub‐micrometer with smooth surfaces reduced fiber diameter (587 ± 191 nm) compared pure PVA (696 ±160 nm). Investigations electrical characteristics demonstrate a fourfold increase conductivity nanofibers (σ = 1.90 0.45 × 10 −8 S cm −1 ) after addition (compared σ 0.46 0.05 PVA‐only fibers). Furthermore, MXene‐PVA system demonstrates nearly twofold stiffness, E 136.87 19.63 MPa than 71.42 16.56 PVA. Moreover, initial vitro experiments indicate L929 cell viability. These findings position composites highly versatile platform advanced devices, such electroactive tissue scaffolds wearable sensors.

Language: Английский

Citations

0
Recent Advances in Potential Biomedical Applications of MXene‐Based Hydrogels DOI
Ali Hamzehlouy, Masoud Tavakoli Dare,

Farangis Shahi

et al.

Polymers for Advanced Technologies, Journal Year: 2024, Volume and Issue: 35(12)

Published: Nov. 29, 2024

ABSTRACT MXene‐based hydrogels represent a significant advancement in biomedical material science, leveraging the unique properties of 2D MXenes and versatile functionality hydrogels. This review discusses recent developments integration into hydrogel matrices, focusing on their applications such as wound healing, drug delivery, antimicrobial activity, tissue engineering, biosensing. MXenes, due to remarkable electrical conductivity, mechanical robustness, tunable surface chemistry, enhance properties, responsiveness environmental stimuli. Specifically, have shown great promise accelerating healing through photothermal effects, delivering drugs controlled manner, serving antibacterial agents. Their also enables targeted cancer therapies, including chemodynamic facilitated by high conductivity properties. Despite promising progress, challenges ensuring biocompatibility optimizing synthesis for large‐scale production remain. aims provide comprehensive overview current state applications, highlighting ongoing advancements potential future directions these multifunctional materials.

Language: Английский

Citations

2