Molybdenum-bridged endo-exogenous antioxidant synergy reverses acute kidney injury via mitochondrial homeostasis reconstruction

IF 18 1区医学 Q1 ENGINEERING, BIOMEDICAL

Bioactive Materials Pub Date : 2025-09-10 DOI:10.1016/j.bioactmat.2025.09.006

Qiaohui Chen , Zuoxiu Xiao , Xiaohong Ying , Yongqi Yang , Jianlin Chen , Ziyu Wu , Wan Zeng , Chenxi Miao , Yayun Nan , Qiong Huang , Kelong Ai

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Abstract

Acute kidney injury (AKI) progression is driven by mitochondrial redox collapse in proximal tubular epithelial cells (PTECs), where reactive oxygen species (ROS) surge and molybdenum (Mo) metabolic dysregulation create an “oxidative storm-defense collapse” cycle. Conventional antioxidant therapies fail to halt AKI chronicity due to their inability to restore Mo-dependent detoxification enzymes (e.g., Mo-containing Amidoxime Reducing Component, mARC). To address this dual pathology, we developed N-acetylcysteine (NAC)-modified molybdenum disulfide quantum dots (NMDs) that implement an endo-exogenous antioxidant collaborative strategy, synergizing exogenous ROS elimination with endogenous Mo enzyme restoration. NMDs achieve triple-tiered targeting: 1) Organ-selective accumulation leveraging NMDs' hydrophilicity and ultrasmall size; 2) Cell-specific internalization through Organic Anion Transporter 1 (OAT1)-mediated active uptake into PTECs; 3) Mitochondrial precision delivery guided by NAC's intrinsic mitochondrial affinity. Within pathological microenvironments, NMDs exhibit multidimensional therapeutic superiority: exposed Mo(Ⅳ) directly quenches mitochondrial ROS via electron transfer (external clearance), while released Mo ions reactivate mARC and NAC supplies glutathione precursors, synergistically rebuilding endogenous antioxidant defenses (internal reinforcement). In vivo validation demonstrated NMDs’ superior therapeutic efficacy, outperforming clinical antioxidant NAC. This work pioneers a “scavenging-fortification” strategy through Mo-centric metabolic regulation and nanotechnology integration, validating Mo-based materials' therapeutic potential and establishing a paradigm for mitochondrial-targeted AKI treatment.

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钼桥内外抗氧化协同作用通过线粒体稳态重建逆转急性肾损伤

急性肾损伤（AKI）的进展是由近端小管上皮细胞（PTECs）的线粒体氧化还原崩溃驱动的，其中活性氧（ROS）激增和钼（Mo）代谢失调创造了一个“氧化风暴防御崩溃”循环。传统的抗氧化疗法由于无法恢复钼依赖的解毒酶（例如，含钼偕胺肟还原组分，mARC）而无法阻止AKI的慢性发展。为了解决这种双重病理，我们开发了n -乙酰半胱氨酸（NAC）修饰的二硫化钼量子点（NMDs），实现了内源性抗氧化协同策略，协同外源性ROS消除和内源性Mo酶恢复。nmd可实现三重靶向：1)利用nmd的亲水性和超小尺寸实现器官选择性积累；2)通过有机阴离子转运蛋白1 （OAT1）介导的ptec主动摄取，实现细胞特异性内化；3) NAC内在线粒体亲和力引导的线粒体精准递送。在病理微环境中，NMDs表现出多方面的治疗优势：暴露的Mo（Ⅳ）通过电子转移（外部清除）直接抑制线粒体ROS，而释放的Mo离子重新激活mARC和NAC，提供谷胱甘肽前体，协同重建内源性抗氧化防御（内部强化）。体内验证表明nmd的治疗效果优于临床抗氧化剂NAC。这项工作通过以钼为中心的代谢调节和纳米技术整合，开创了一种“清除-强化”策略，验证了钼基材料的治疗潜力，并建立了线粒体靶向AKI治疗的范例。

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来源期刊

Bioactive Materials Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

28.00

自引率

6.30%

发文量

436

审稿时长

20 days

期刊介绍： Bioactive Materials is a peer-reviewed research publication that focuses on advancements in bioactive materials. The journal accepts research papers, reviews, and rapid communications in the field of next-generation biomaterials that interact with cells, tissues, and organs in various living organisms. The primary goal of Bioactive Materials is to promote the science and engineering of biomaterials that exhibit adaptiveness to the biological environment. These materials are specifically designed to stimulate or direct appropriate cell and tissue responses or regulate interactions with microorganisms. The journal covers a wide range of bioactive materials, including those that are engineered or designed in terms of their physical form (e.g. particulate, fiber), topology (e.g. porosity, surface roughness), or dimensions (ranging from macro to nano-scales). Contributions are sought from the following categories of bioactive materials: Bioactive metals and alloys Bioactive inorganics: ceramics, glasses, and carbon-based materials Bioactive polymers and gels Bioactive materials derived from natural sources Bioactive composites These materials find applications in human and veterinary medicine, such as implants, tissue engineering scaffolds, cell/drug/gene carriers, as well as imaging and sensing devices.