Magnetoelectric Microrobots for Spinal Cord Injury Regeneration

bioRxiv Pub Date : 2024-08-08 DOI:10.1101/2024.08.06.606378
Hao Ye, J. Zang, Jiawei Zhu, D. Arx, Vitaly Pustovalov, Minmin Mao, Qiao Tang, Andrea Veciana, Harun Torlakcik, Elric Zhang, S. Sevim, R. Sanchis-Gual, Xiang-Zhong Chen, Daniel Ahmed, M. V. Sanchez-Vives, Josep Puigmartí‐Luis, Bradley J. Nelson, S. Neuhauss, Salvador Pané
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Abstract

Regenerative medicine continually seeks effective methods to address spinal cord injuries (SCI), which are known for their limited regenerative potential. Despite advances in neural progenitor cell (NPC) transplants for spinal cord injuries, challenges related to graft survival, reliable in vivo differentiation, and neural integration significantly hinder real functional recovery and limit clinical outcomes. This study introduces ‘NPCbots’, biohybrid microrobots engineered by integrating human-induced pluripotent stem cell-derived NPCs with magnetoelectric nanoparticles composed of cobalt ferrite-barium titanate. These enable magnetic navigation and neuronal stimulation, enhancing targeted therapeutic interventions. Our lab-on-a-chip system allows for the mass production of NPCbots, ensuring their differentiation and biocompatibility. Remarkably, in a zebrafish model of SCI, NPCbots stimulated by an alternating magnetic field demonstrated rapid in vivo differentiation and integration into damaged neural pathways, significantly enhancing neural regeneration. Within three days, injured zebrafish treated with NPCbots exhibited almost normal swimming behavior and significantly improved exploratory behavior, showcasing the potential of NPCbots to swiftly repair neural structures and restore the central nervous system’s functionality in spinal cord injury models through non-invasive means. Additionally, precise in vitro and in vivo manipulation of NPCbots indicates their broader application in various neurodegenerative disorders, offering a promising route for effective spinal cord and neurological recovery.
用于脊髓损伤再生的磁电微型机器人
再生医学一直在寻求解决脊髓损伤(SCI)的有效方法,众所周知,脊髓损伤的再生潜力有限。尽管神经祖细胞(NPC)移植在治疗脊髓损伤方面取得了进展,但与移植物存活、可靠的体内分化和神经整合相关的挑战极大地阻碍了真正的功能恢复并限制了临床结果。本研究介绍了 "NPCbots",即通过将人类诱导多能干细胞衍生的NPC与由钴铁氧体-钛酸钡组成的磁电纳米粒子整合而设计的生物混合微型机器人。这些纳米粒子可实现磁导航和神经元刺激,从而增强靶向治疗干预。我们的片上实验室系统可实现 NPC 机器人的批量生产,确保其分化和生物兼容性。令人瞩目的是,在斑马鱼 SCI 模型中,受交变磁场刺激的 NPCbots 在体内迅速分化并整合到受损的神经通路中,显著促进了神经再生。在三天内,接受NPCbots治疗的受伤斑马鱼表现出几乎正常的游泳行为,探索行为也得到明显改善,这展示了NPCbots通过非侵入性手段在脊髓损伤模型中迅速修复神经结构和恢复中枢神经系统功能的潜力。此外,对NPCbots进行精确的体外和体内操作表明,它们在各种神经退行性疾病中的应用更为广泛,为脊髓和神经系统的有效恢复提供了一条前景广阔的途径。
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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