Materials Science and Engineering Program, University of California Riverside, 900 University Avenue, Riverside, CA 92521, United States; Department of Bioengineering, University of California Riverside, 900 University Avenue, Riverside, CA 92521, United States.
Neuroscience Graduate Program, University of California Riverside, 900 University Avenue, Riverside, CA 92521, United States.
Mater Sci Eng C Mater Biol Appl. 2020 May;110:110614. doi: 10.1016/j.msec.2019.110614. Epub 2020 Jan 3.
This article reports fabrication, characterization, degradation and electrical properties of biodegradable magnesium (Mg) microwires coated with two functional polymers, and the first in vivo evidence on the feasibility of Mg-based biodegradable microelectrodes for neural recording. Conductive poly(3,4‑ethylenedioxythiophene) (PEDOT) coating was first electrochemically deposited onto Mg microwire surface, and insulating biodegradable poly(glycerol sebacate) (PGS) was then spray-coated onto PEDOT surface to improve the overall properties of microelectrode. The assembled PGS/PEDOT-coated Mg microelectrodes showed high homogeneity in coating thickness, surface morphology and composition before and after in vivo recording. The charge storage capacity (CSC) of PGS/PEDOT-coated Mg microwire (1.72 mC/cm) was nearly 5 times higher than the standard platinum (Pt) microwire widely used in implantable electrodes. The Mg-based microelectrode demonstrated excellent neural-recording capability and stability during in vivo multi-unit neural recordings in the auditory cortex of a mouse. Specifically, the Mg-based electrode showed clear and stable onset response, and excellent signal-to-noise ratio during spontaneous-activity recordings and three repeats of stimulus-evoked recordings at two different anatomical locations in the auditory cortex. During 10 days of immersion in artificial cerebrospinal fluid (aCSF) in vitro, PGS/PEDOT-coated Mg microelectrodes showed slower degradation and less change in impedance than PEDOT-coated Mg electrodes. The biodegradable PGS coating protected the PEDOT coating from delamination, and prolonged the mechanical integrity and electrical properties of Mg-based microelectrode. Mg-based novel microelectrodes should be further studied toward clinical translation because they can potentially eliminate the risks and costs associated with secondary surgeries for removal of failed or no longer needed electrodes.
本文报道了具有生物降解性能的镁(Mg)微米线的制备、表征、降解和电性能,以及基于 Mg 的生物可降解微电极用于神经记录的首例体内可行性证据。首先在 Mg 微米线表面电沉积导电聚(3,4-亚乙基二氧噻吩)(PEDOT)涂层,然后将可生物降解的聚(甘油琥珀酸酯)(PGS)喷涂到 PEDOT 表面,以提高微电极的整体性能。组装的 PGS/PEDOT 涂层 Mg 微电极在体内记录前后具有均匀的涂层厚度、表面形貌和组成。PGS/PEDOT 涂层 Mg 微米线的电荷存储能力(CSC)(1.72 mC/cm)比广泛用于植入式电极的标准铂(Pt)微米线高近 5 倍。基于 Mg 的微电极在小鼠听觉皮层的体内多单位神经记录中表现出优异的神经记录能力和稳定性。具体而言,基于 Mg 的电极在自发活动记录和听觉皮层两个不同解剖位置的三次刺激诱发记录期间表现出清晰和稳定的起始反应以及优异的信噪比。在体外人工脑脊液(aCSF)中浸泡 10 天期间,PGS/PEDOT 涂层 Mg 微电极的降解速度较慢,阻抗变化较小,而 PEDOT 涂层 Mg 微电极则较慢。可生物降解的 PGS 涂层保护 PEDOT 涂层免受分层,延长了基于 Mg 的微电极的机械完整性和电性能。具有生物降解性能的新型 Mg 微电极应该进一步研究其临床转化,因为它们可以潜在地消除与二次手术相关的风险和成本,以去除失效或不再需要的电极。
