A facile preparation of FePt-loaded few-layer MoS2 nanosheets nanocomposites (F-MoS2-FePt NCs) and their application for colorimetric detection of H2O2 in living cells.

BACKGROUND: Rapid and sensitive detection of H2O2 especially endogenous H2O2 is of great importance for series of industries including disease diagnosis and therapy. In this work, uniform FePt nanoparticles are successfully anchored onto Few-layer molybdenum disulfide nanosheets (F-MoS2 NSs). The powder X-ray diffraction, transmission electron microscopy, UV-Vis spectra and atomic force microscopy were employed to confirm the structure of the obtained nanocomposites (F-MoS2-FePt NCs). The prepared nanocomposites show efficient peroxidase-like catalytic activities verified by catalyzing the peroxidation substrate 4,4'-diamino-3,3',5,5'-tetramethylbiphenyl (TMB) with the existence of H2O2. RESULTS: The optimal conditions of the constructed colorimetric sensing platform is proved as 35 °C and pH 4.2. Under optimal catalytic conditions, the detection limit for H2O2 detection reaches 2.24 µM and the linear ranger is 8 µM to 300 µM. Furthermore, the proposed colorimetric sensing platform was successfully utilized to detect the intracellular H2O2 of cancer cells (MCF-7). CONCLUSIONS: These findings indicated that the F-MoS2-FePt-TMB-H2O2 system provides a potential sensing platform for hydrogen peroxide monitoring in living cells.

A novel theranostic nano-platform (PB@FePt-HA-g-PEG) for tumor chemodynamic-photothermal co-therapy and triple-modal imaging (MR/CT/PI) diagnosis.

The construction of multi-functional oncotherapy nano-platforms combining diagnosis and therapy remains a tough challenge. Prussian blue nano-cubes with optimized particle size were applied as photothermal agents and loaded with FePt NPs, effective ferroptosis agents, on the surface via an in situ reduction strategy. To attain the goal of precise medicine, hyaluronic acid was wrapped around the surface of the nanocomposites (PB@FePt NCs) for highly specific recognition of tumor cells. Finally, we successfully designed and fabricated a nano-agent (PB@FePt-HA-g-PEG NCs) to serve as a versatile nano-platform with both highly specific targeting ability for chemodynamic-photothermal co-therapy and triple-modal imaging (magnetic resonance/computed tomography/photothermal imaging) capability. Via intravenous injection, the as-constructed oncotherapy nano-platform could effectively ablate 4T1 tumor xenografts with excellent biocompatibility for chemodynamic-photothermal co-therapy. In this study we conducted a reasonable exploration to design multi-functional oncotherapy nano-platforms combining multiplexed imaging diagnosis and high therapeutic performance, which provides an innovative paradigm for precision cancer treatment.