LDH nanoparticles-doped cellulose nanofiber scaffolds with aligned microchannels direct high-efficiency neural regeneration and organized neural circuit remodeling through RhoA/Rock/Myosin II pathway

IF 12.8 1区医学 Q1 ENGINEERING, BIOMEDICAL

Biomaterials Pub Date : 2024-10-02 DOI:10.1016/j.biomaterials.2024.122873

Xuening Pang , Tongling Zhang , Jiazheng Li , Liqun Yu , Zhibo Liu , Yuchen Liu , Li Li , Liming Cheng , Rongrong Zhu

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引用次数: 0

Abstract

Spinal cord injury (SCI) triggers interconnected malignant pathological cascades culminating in structural abnormalities and composition changes of neural tissues and impairs spinal cord tissue function. Cellulose nanofibers (CNF) have considerable potential in mimicking tissue microstructure for nerve regeneration, but the effectiveness of CNF in repairing SCI remains poorly understood. In this study, we designed a Mg–Fe layered double hydroxide (LDH)-doped cellulose nanofiber (CNF) scaffold with aligned intact microchannels and homogeneously distributed pores (CNF-LDH), loaded with retinoic acid and sonic hedgehog (CNF-LDH-RS) for neuroregeneration. The aligned microchannel structure and chemical cues in the scaffold were designed further to enhance the differentiation of neural stem cells towards neurons and promote axon growth while inhibiting differentiation to astrocytes. Transplanting the scaffolds into a completely transected SCI mice model dramatically improved behavioral and electrophysiological outcomes underpinned by robust neuronal regeneration, significant axonal growth and orderly neural circuit remodeling. RNA-seq analysis revealed the pivotal roles of the RhoA/Rock/Myosin II pathway and neuroactive ligand-receptor interaction pathway in SCI repair by CNF-LDH-RS. Particularly, Myosin II emerged as a key gene for functional recovery, and its effect on negative regulation of axon growth was suppressed by the scaffolds, resulting in a distinctly oriented growth of the axons along the microchannel structure. The results indicate that CNF-LDH scaffolds rationally combined with physical and biochemical cues create promising tissue-engineered substrates to facilitate the repair of spinal cord injury.

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掺杂 LDH 纳米颗粒的纤维素纳米纤维支架具有排列整齐的微通道，可通过 RhoA/Rock/Myosin II 通路引导高效的神经再生和有组织的神经回路重塑。

脊髓损伤（SCI）会引发相互关联的恶性病理级联，最终导致神经组织的结构异常和成分变化，并损害脊髓组织的功能。纤维素纳米纤维（CNF）在模拟组织微观结构促进神经再生方面具有相当大的潜力，但人们对 CNF 修复 SCI 的效果仍知之甚少。在这项研究中，我们设计了一种掺杂镁铁双层氢氧化物（LDH）的纤维素纳米纤维（CNF）支架，它具有排列整齐的完整微通道和均匀分布的孔隙（CNF-LDH），并负载有维甲酸和声刺猬（CNF-LDH-RS），用于神经再生。通过进一步设计支架中排列整齐的微通道结构和化学线索，可增强神经干细胞向神经元的分化，促进轴突生长，同时抑制向星形胶质细胞的分化。将支架移植到完全横断的 SCI 小鼠模型中，可显著改善神经元再生、轴突生长和有序神经回路重塑所带来的行为和电生理结果。RNA-seq分析揭示了RhoA/Rock/肌球蛋白II通路和神经活性配体-受体相互作用通路在CNF-LDH-RS修复SCI中的关键作用。尤其是肌球蛋白II是功能恢复的关键基因，它对轴突生长的负调控作用被支架抑制，导致轴突沿微通道结构明显定向生长。研究结果表明，CNF-LDH支架与物理和生化线索合理结合，可创造出前景广阔的组织工程基底，促进脊髓损伤的修复。

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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.