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Microenvironment-adaptive nanomedicine MXene promotes flap survival by inhibiting ROS cascade and endothelial pyroptosis

Ningning Yang, Rongrong Hua, Yingying Lai, P. L. Zhu, Jian Ding, Xianhui Ma, Gaoxiang Yu, Yiheng Xia, Chao Liang, Weiyang Gao, Zhouguang Wang, Hongyu Zhang, Liangliang Yang, Kailiang Zhou, Lu Ge

2025Journal of Nanobiotechnology24 citationsDOIOpen Access PDF

Abstract

In the field of large-area trauma flap transplantation, preventing avascular necrosis remains a critical challenge. Key mechanisms for improving flap viability include angiogenesis promotion, oxidative stress inhibition, and cell death prevention. Recently, two-dimensional ultrathin Ti3C2TX (MXene) nanosheets have gained attention for their potential contributions to these processes, though MXene’s physiological impact on flap survival had not been previously investigated. This study is the first to confirm MXene's biological effects on the ischaemic microenvironment post-skin flap transplantation. Findings indicated that MXene significantly decreased the necrotic area in ischaemic flaps (37.96% ± 2.00%), with reductions of 30.40% ± 1.86% at 1 mg/mL and 20.19% ± 2.11% at 2 mg/mL in a concentration-dependent manner. Mechanistically, MXene facilitated in situ angiogenesis, mitigated oxidative stress, suppressed pro-inflammatory pyroptosis, and activated the PI3K-Akt pathway, particularly influencing vascular endothelial cells. Comparative transcriptome analysis of skin tissues with and without MXene treatment provided additional evidence, highlighting mechanisms such as pro-inflammatory pyroptosis, ROS metabolic processes, endothelial cell proliferation regulation, and PI3K-Akt signaling pathway activation. Overall, MXene demonstrated biological activity, effectively promoting ischaemic flaps survival and presenting a novel strategy for addressing ischaemic necrosis in skin flaps.

Topics & Concepts

PyroptosisNanomedicineCell biologyChemistryBiomimetic materialsNanotechnologyApoptosisBiologyBiochemistryMaterials scienceProgrammed cell deathNanoparticleMXene and MAX Phase MaterialsGraphene and Nanomaterials ApplicationsDendrimers and Hyperbranched Polymers