Air bag-embedded MIL-101(Fe) metal-organic frameworks for an amplified tumor microenvironment activation loop through strategic delivery of iron ions and lentinan.
Tao Han, Yan Sun, Xi Jiang, Chengming Gong, Fei Kong, Yi Luo, Chang Ge, Congyan Liu, Yuping Liu, Yanfei Mou, Huangqin Zhang, Jianming Ju, Yan Chen, Ding Qu
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引用次数: 0
Abstract
Background: Iron-based nanocarriers have demonstrated potential in redirecting tumor associated macrophages (TAMs) polarization towards the M1 phenotype, critical for activating the tumor microenvironment (TME) in triple negative breast cancer (TNBC). However, their real-world effectiveness is curtailed by insufficient Fe2+/3+ exposure and the absence of suitable synergists in tumors. Methods: We introduce an air bag-embedded iron-based MIL-101 metal-organic frameworks (MOFMIL-101(Fe)) for igniting the TME in TNBC through bubble-driven tumoral codelivery of Fe2+/3+ and lentinan. This system, named HM/Ef/LNT-MOFMIL-101(Fe), features nano-sized MOFMIL-101(Fe) as the core, embedded NaHCO3 as a pH-triggered air bag, electrostatically-adsorbed lentinan forming the inner shell, and a shield shell with 4T1&red blood cell hybrid membrane. Results: HM/Ef/LNT-MOFMIL-101(Fe) can mitigate non-specific capture in the bloodstream but respond to the acidic tumor milieu, rapidly generating a burst of CO2 bubbles to disassemble MOFMIL-101(Fe). Upon entering tumors, lentinan-induced interferon-γ (IFN-γ) enable Fe2+/3+ facilitating an enhanced ferroptosis and Fenton-like reaction, pushing TAMs towards M1 polarization via the "IFN-γ-ferroptosis-ROS-Caspase-3" pathway. Moreover, HM/Ef/LNT-MOFMIL-101(Fe) increases the infiltration of T lymphocytes and decreases regulatory T cells. These cascading immune responses synergistically foster a loop of amplified TME activation based on TAMs M1 polarization, showcasing notable advancements in anticancer effectiveness and promise for various combination therapies. Conclusion: This study utilizes an "embedded air-bag" strategy to achieve strategic codelivery of Fe2+/3+ and lentinan, providing a new tool for engineering the TME.
期刊介绍:
Theranostics serves as a pivotal platform for the exchange of clinical and scientific insights within the diagnostic and therapeutic molecular and nanomedicine community, along with allied professions engaged in integrating molecular imaging and therapy. As a multidisciplinary journal, Theranostics showcases innovative research articles spanning fields such as in vitro diagnostics and prognostics, in vivo molecular imaging, molecular therapeutics, image-guided therapy, biosensor technology, nanobiosensors, bioelectronics, system biology, translational medicine, point-of-care applications, and personalized medicine. Encouraging a broad spectrum of biomedical research with potential theranostic applications, the journal rigorously peer-reviews primary research, alongside publishing reviews, news, and commentary that aim to bridge the gap between the laboratory, clinic, and biotechnology industries.