Table 6.
The application of MXene in wound healing
| MXenes | Scaffold type | Result | Reference |
|---|---|---|---|
| Ti3C2Tx | composite hydrogels | High toughness, anisotropy, antibacterial activity and cell proliferation | [78] |
| Ti3C2Tx | composite sponge | Enhanced hemostatic effect | [79] |
| Ti3C2Tx | HPEM scaffolds | Excellent rheological properties, self-healing properties, electrical conductivity and tissue adhesion properties | [80] |
| Ti3C2Tx | FOM scaffolds | Injectable, antibacterial, conductive and quick hemostatic | [81] |
| Ti3C2Tx | Ag/ Ti3C2Tx composites | Bacteria inhibit and promote wound healing | [82] |
| Ti3C2Tx | MZ-8/PLA composite membrane | Accelerates bacterial wound healing without developing drug resistance | [83] |
| Ti3C2Tx | Interface Schottky junction | Antibacterial and promote wound healing | [85] |
| Ti3C2Tx | PLGA membranes | Antibacterial, hemostatic, promote wound local collagen deposition and promote angiogenesis | [86] |
| Ti3C2 | Ti3C2/MoS2 bioheterojunction | Photothermal, photodynamic, peroxidase - like and glutathione oxidase - like properties | [87] |
| Ti3C2Tx | rBC/MXene hydrogels | In response to exogenous electrical stimulation | [96] |
| Ti3C2Tx | Double-net hydrogels | Controlled drug delivery capability | [99] |
| Ti3C2Tx | K-M/PNIPAm hydrogel dressing | Photocontrolled drug release ability | [100] |
| Ti3C2Tx | PEGDA microneedle patch | Promote angiogenesis, accelerate wound healing and active delivery | [103] |
| Ti3C2Tx | Biomimetic microneedle patches | Controlled drug release | [104] |
| Ti3C2Tx | MXene-AMX-PVA nanofibrous membrane | Physical barrier, high antibacterial | [106] |