时空控制超声驱动Li-PDA@ZnO纳米颗粒促进神经干细胞分化协同生物水凝胶修复脊髓损伤

IF 18 1区医学 Q1 ENGINEERING, BIOMEDICAL

Bioactive Materials Pub Date : 2025-09-29 DOI:10.1016/j.bioactmat.2025.07.050

Dapeng Zhang , Xiaolong Zhou , Chenxi Zhao , Shuwei Han , Xianzheng Guo , Haosheng Chen , Wenzhao Wang , Wencan Zhang , Mingzheng Chang , Qingliang Ma , Yunhao You , Mingshan Liu , Xinyu Liu , Zhijian Wei , Xiaohong Kong , Shiqing Feng

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引用次数: 0

摘要

脊髓损伤后神经元丢失是影响神经功能恢复的重要障碍。神经干细胞（NSCs）补充提供了一个有前途的治疗途径，提供种子细胞；然而，NSCs向神经元的分化率往往不是最优的。在本研究中，利用聚多巴胺涂层将锂固定在ZnO纳米颗粒表面，合成Li-PDA@ZnO纳米颗粒。这些纳米颗粒被设计成在超声驱动刺激下以时空控制的方式诱导NSC分化为神经元。此外，研究人员还开发了一种由genipin和胶原组成的生物水凝胶系统，用于包封预载内吞纳米颗粒的NSCs。超声刺激氧化锌纳米颗粒可促进NSCs内吞作用后向神经元的分化，并呈浓度依赖性。Li-PDA@ZnO纳米颗粒表现出更好的生物相容性，并进一步促进神经元分化，这是一个由ERK和ASCL1介导的分子途径。在体内，通过小鼠脊髓损伤模型验证了超声驱动纳米颗粒增强NSC分化的能力。此外，在脊髓损伤横断模型中对纳米颗粒-生物水凝胶组合系统进行了评估，发现它可以减少局部炎症，增强NSCs的神经元分化，增加功能神经元的比例。这些效果显著改善了脊髓损伤后运动、感觉和自主神经功能的恢复。综上所述，时空控制的超声驱动Li-PDA@ZnO纳米颗粒有效地增强了NSCs向神经元的分化，并且当纳入水凝胶系统时，代表了一种新的脊髓损伤修复治疗方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Spatiotemporal-controlled ultrasound-driven Li-PDA@ZnO nanoparticles promote neural stem cell differentiation synergy with biohydrogel repair spinal cord injury

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Spatiotemporal-controlled ultrasound-driven Li-PDA@ZnO nanoparticles promote neural stem cell differentiation synergy with biohydrogel repair spinal cord injury

Neuronal loss following spinal cord injury (SCI) remains a significant barrier to the recovery of neural function. Neural stem cells (NSCs) supplementation offers a promising therapeutic avenue by providing seed cells; however, the differentiation rate of NSCs into neurons is often suboptimal. In this study, lithium was immobilized on the surface of ZnO nanoparticles using a polydopamine coating to synthesize Li-PDA@ZnO nanoparticles. These nanoparticles were designed to induce NSC differentiation into neurons in a spatiotemporal-controlled manner using ultrasound-driven stimulation. Additionally, a biohydrogel system consisting of genipin and collagen was developed to encapsulate NSCs preloaded with endocytosed nanoparticles. The application of ultrasound stimulation to ZnO nanoparticles enhanced the differentiation of NSCs into neurons in a concentration-dependent manner following endocytosis. Li-PDA@ZnO nanoparticles demonstrated improved biocompatibility and further promoted neuronal differentiation, a process mediated by molecular pathways involving ERK and ASCL1. In vivo, the ability of ultrasound-driven nanoparticles to enhance NSC differentiation was validated using a mouse SCI contusion model. Furthermore, the combined nanoparticle-biohydrogel system was evaluated in an SCI transection model, where it was found to reduce local inflammation, enhance neuronal differentiation of NSCs, and increase the proportion of functional neurons. These effects contributed to significant improvements in motor, sensory, and autonomic function recovery following SCI. In summary, spatiotemporal-controlled ultrasound-driven Li-PDA@ZnO nanoparticles effectively enhance the differentiation of NSCs into neurons and, when incorporated into hydrogel systems, represent a novel therapeutic approach for spinal cord injury repair.

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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.