用于mri兼容脑接口电极的可注射和组织适应的导电水凝胶

Soft science Pub Date : 2023-01-01 DOI:10.20517/ss.2023.08
Song Dong Kim, Kyuha Park, Sungjun Lee, Jeungeun Kum, Yewon Kim, Soojung An, Hyungmin Kim, M. Shin, Donghee Son
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引用次数: 0

摘要

柔性和可拉伸材料的发展导致了植入式生物集成电子设备的进步,这些设备可以感知生理信号或向人体各器官传递电刺激。这种设备对于实时监测神经退行性疾病(如帕金森病或癫痫)的神经接口系统特别有用。然而,由于无机金属基设备的共振频率变化,将当前的脑接口设备与磁共振成像(MRI)耦合仍然是一个实际的挑战。因此,有机导电材料,如聚(3,4-乙烯二氧噻吩)-聚苯乙烯磺酸盐(PEDOT:PSS),最近被认为是有前途的候选者。尽管如此,它们在曲线组织上的顺应性仍然值得怀疑。在这项研究中,我们开发了一种由酪胺偶联透明质酸(HATYR)和PEDOT:PSS组成的可注射导电水凝胶(ICH),用于mri兼容的脑接口电极。我们的ICH即使在10 Hz以下也能产生5 kΩ左右的低阻抗,显示出高置信度的体积电容。由于HATYR的生物相容性,组织学和细胞毒性试验分别显示几乎没有炎症和毒性;此外,ICH能够在体内4周内降解为原始体积的40%。脑皮质电图(ECoG)阵列也可以通过注射器将ICH注射到符合弯曲脑组织的可拉伸和柔性弹性衬底层上,并成功记录光刺激下的ECoG信号。此外,植入设备的MRI成像未显示任何伪影,表明MRI兼容水凝胶电极用于先进的ECoG阵列的潜力。这项研究为mri兼容的神经电极提供了一个有希望的解决方案,使监测神经退行性疾病的慢性神经接口系统的进步成为可能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Injectable and tissue-conformable conductive hydrogel for MRI-compatible brain-interfacing electrodes
The development of flexible and stretchable materials has led to advances in implantable bio-integrated electronic devices that can sense physiological signals or deliver electrical stimulation to various organs in the human body. Such devices are particularly useful for neural interfacing systems that monitor neurodegenerative diseases such as Parkinson’s disease or epilepsy in real time. However, coupling current brain-interfacing devices with magnetic resonance imaging (MRI) remains a practical challenge due to resonance frequency variations from inorganic metal-based devices. Thus, organic conductive materials, such as poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) (PEDOT:PSS), have recently been considered as promising candidates. Nonetheless, their conformability on curvilinear tissues remains questionable. In this study, we developed an injectable conductive hydrogel (ICH) composed of tyramine-conjugated hyaluronic acid (HATYR) and PEDOT:PSS for MRI-compatible brain-interfacing electrodes. Our ICH produced low impedance around 5 kΩ even under 10 Hz, demonstrating high confidence volumetric capacitance. Due to HATYR’s biocompatibility, histological and cytotoxicity assays showed almost no inflammation and toxicity, respectively; in addition, ICH was able to degrade into 40% of its original volume within four weeks in vivo. An electrocorticogram (ECoG) array was also patternable by syringe injections of ICH on a stretchable and flexible elastomeric substrate layer that conformed to curvy brain tissues and successfully recorded ECoG signals under light stimulation. Furthermore, MRI imaging of implanted devices did not show any artifacts, indicating the potential of the MRI-compatible hydrogel electrodes for advanced ECoG arrays. This study provides a promising solution for MRI-compatible neural electrodes, enabling the advancement of chronic neural interfacing systems for monitoring neurodegenerative diseases.
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