Dynamic changes in the structure and function of brain mural cells around chronically implanted microelectrodes

IF 12.8 1区 医学 Q1 ENGINEERING, BIOMEDICAL Biomaterials Pub Date : 2024-11-12 DOI:10.1016/j.biomaterials.2024.122963
Steven M. Wellman , Adam M. Forrest , Madeline M. Douglas , Ashwat Subbaraman , Guangfeng Zhang , Takashi D.Y. Kozai
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Abstract

Integration of neural interfaces with minimal tissue disruption in the brain is ideal to develop robust tools that can address essential neuroscience questions and combat neurological disorders. However, implantation of intracortical devices provokes severe tissue inflammation within the brain, which requires a high metabolic demand to support a complex series of cellular events mediating tissue degeneration and wound healing. Pericytes, peri-vascular cells involved in blood-brain barrier maintenance, vascular permeability, waste clearance, and angiogenesis, have recently been implicated as potential perpetuators of neurodegeneration in brain injury and disease. While the intimate relationship between pericytes and the cortical microvasculature have been explored in other disease states, their behavior following microelectrode implantation, which is responsible for direct blood vessel disruption and dysfunction, is currently unknown. Using two-photon microscopy we observed dynamic changes in the structure and function of pericytes during implantation of a microelectrode array over a 4-week implantation period. Pericytes respond to electrode insertion through transient increases in intracellular calcium and underlying constriction of capillary vessels. Within days following the initial insertion, we observed an influx of new, proliferating pericytes which contribute to new blood vessel formation. Additionally, we discovered a potentially novel population of reactive immune cells in close proximity to the electrode-tissue interface actively engaging in encapsulation of the microelectrode array. Finally, we determined that intracellular pericyte calcium can be modulated by intracortical microstimulation in an amplitude- and frequency-dependent manner. This study provides a new perspective on the complex biological sequelae occurring at the electrode-tissue interface and will foster new avenues of potential research consideration and lead to development of more advanced therapeutic interventions towards improving the biocompatibility of neural electrode technology.
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长期植入微电极周围脑壁细胞结构和功能的动态变化。
将神经接口与对大脑组织破坏最小的设备整合在一起,是开发强大工具的理想选择,这些工具可以解决重要的神经科学问题,防治神经系统疾病。然而,皮质内装置的植入会引发脑内严重的组织炎症,需要大量新陈代谢来支持一系列介导组织变性和伤口愈合的复杂细胞事件。周细胞是参与血脑屏障维护、血管通透性、废物清除和血管生成的血管周围细胞,最近被认为是脑损伤和疾病中神经变性的潜在延续者。虽然在其他疾病状态下已对周细胞与大脑皮层微血管之间的密切关系进行了探讨,但目前还不清楚它们在微电极植入后的行为会直接导致血管破坏和功能障碍。我们使用双光子显微镜观察了微电极阵列植入 4 周后周细胞结构和功能的动态变化。周细胞通过细胞内钙的短暂增加和毛细血管的潜在收缩对电极的插入做出反应。在首次插入后的几天内,我们观察到大量新的、增殖的周细胞涌入,这有助于新血管的形成。此外,我们还在电极-组织界面附近发现了潜在的新型反应性免疫细胞群,它们正积极地参与微电极阵列的封装。最后,我们确定细胞周质内的钙可以通过皮层内微刺激以振幅和频率依赖的方式进行调节。这项研究为了解电极-组织界面发生的复杂生物后遗症提供了一个新的视角,并将为潜在的研究开辟新的途径,从而开发出更先进的治疗干预措施,改善神经电极技术的生物兼容性。
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
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.
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