Ultrasound-activated piezoelectric heterojunction drives nanozyme catalysis to induce bacterial cuproptosis-like death and promote bone vascularization and osseointegration

IF 12.8 1区医学 Q1 ENGINEERING, BIOMEDICAL

Biomaterials Pub Date : 2025-03-05 DOI:10.1016/j.biomaterials.2025.123249

Longhai Qiu , Sushuang Ma , Ren Yang , Dengwen Zheng , Yuliang Huang , Zhengwei Zhu , Sijun Peng , Mei Li , Hua Zhong , Feng Peng

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Abstract

Osteomyelitis is a severe and persistent bone infection that poses significant challenges to clinical treatment, often requiring prolonged antibiotic therapy and invasive procedures. Nanomaterial-based non-antibiotic therapies have emerged as promising alternatives in combating bacterial infections. However, effectively treating osteomyelitis while simultaneously promoting bone repair remains a challenge. Herein, we developed a nanoheterojunction catalytic reactor composed of copper ferrite (CuFe₂O₄) and molybdenum disulfide (MoS₂) quantum dots (CFO@MoS₂), leveraging ultrasound catalysis in combination with copper ions to induce bacterial cuproptosis-like death. Theoretical calculations indicate that the establishment of a heterojunction interface can accelerate oxygen adsorption, inducing electron flow toward oxygen atoms at the interface, thereby enhancing the separation of interface electron-hole pairs. Furthermore, copper ions released from CFO@MoS₂ undergo valence state changes under ultrasound, activating the Fenton reaction and releasing reactive oxygen species to kill bacteria. Gene sequencing shows that CFO@MoS₂, when activated by ultrasound, disrupts bacterial energy synthesis, interferes with bacterial metabolism, and induces copper-related bacterial death. More importantly, the microcurrents generated by ultrasound synergistic with the released copper and iron ions stimulate the expression of angiogenic and osteogenic genes, promoting bone regeneration. The ultrasound-triggered catalytic reaction by CFO@MoS₂ disrupts bacterial homeostasis, accelerates bacterial death, and offers a novel therapeutic strategy for osteomyelitis.

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超声激活压电异质结驱动纳米酶催化诱导细菌铜裂样死亡，促进骨血管形成和骨整合

骨髓炎是一种严重和持续的骨感染，对临床治疗提出了重大挑战，通常需要长期的抗生素治疗和侵入性手术。基于纳米材料的非抗生素疗法已经成为对抗细菌感染的有希望的替代方法。然而，有效地治疗骨髓炎，同时促进骨修复仍然是一个挑战。在此，我们开发了一种由铁氧体铜（CuFe2O4）和二硫化钼（MoS2）量子点组成的纳米异质结催化反应器（CFO@MoS2），利用超声催化与铜离子结合诱导细菌铜中毒样死亡。理论计算表明，异质结界面的建立可以加速氧的吸附，诱导电子流向界面处的氧原子，从而增强界面电子-空穴对的分离。此外，CFO@MoS2释放的铜离子在超声作用下发生价态变化，激活Fenton反应，释放活性氧杀死细菌。基因测序显示，CFO@MoS2被超声波激活时，会破坏细菌能量合成，干扰细菌代谢，并诱发与铜相关的细菌死亡。更重要的是，超声产生的微电流与释放的铜和铁离子协同作用，刺激血管生成和成骨基因的表达，促进骨再生。超声波触发的催化反应CFO@MoS2破坏细菌稳态，加速细菌死亡，并为骨髓炎提供了一种新的治疗策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Biomaterials 工程技术-材料科学：生物材料

CiteScore

26.00

自引率

2.90%

发文量

565

审稿时长

46 days

期刊介绍： Biomaterials is an international journal covering the science and clinical application of biomaterials. A biomaterial is now defined as a substance that has been engineered to take a form which, alone or as part of a complex system, is used to direct, by control of interactions with components of living systems, the course of any therapeutic or diagnostic procedure. It is the aim of the journal to provide a peer-reviewed forum for the publication of original papers and authoritative review and opinion papers dealing with the most important issues facing the use of biomaterials in clinical practice. The scope of the journal covers the wide range of physical, biological and chemical sciences that underpin the design of biomaterials and the clinical disciplines in which they are used. These sciences include polymer synthesis and characterization, drug and gene vector design, the biology of the host response, immunology and toxicology and self assembly at the nanoscale. Clinical applications include the therapies of medical technology and regenerative medicine in all clinical disciplines, and diagnostic systems that reply on innovative contrast and sensing agents. The journal is relevant to areas such as cancer diagnosis and therapy, implantable devices, drug delivery systems, gene vectors, bionanotechnology and tissue engineering.