Author:
Zhou Wenjianlong,Jiang Yuanwen,Xu Qin,Chen Liangpeng,Qiao Hui,Wang Yixuan,Lai Jiancheng,Zhong Donglai,Zhang Yuan,Li Weining,Du Yanru,Wang Xuecheng,Lei Jiaxin,Dong Gehong,Guan Xiudong,Ma Shunchang,Kang Peng,Yuan Linhao,Zhang Milin,Tok Jeffrey B.-H.,Li Deling,Bao Zhenan,Jia Wang
Abstract
AbstractContinuous intra-operative neurophysiological monitoring (CINM) that provides precise mapping of neural anatomy through the entire microsurgery process is essential to preserve the structural and functional integrity of the nerve. However, bulky and rigid electrodes used currently in clinics are usually unable to reliably maintain continuous and stable contacts with the vulnerable and complex nerve networks, thus often resulting in detrimental post-operative complications, such as hemiplegia and sensory disturbances. Here, we describe a biomechanically compatible, suture-free, and individually reconfigurable CINM based on soft and stretchable organic electronic materials. Due to both low impedance and modulus of our conducting polymer electrodes, we achievedfor the first timecontinuous recording of near-field action potential with high signal-to-noise ratio and minimal invasiveness during microsurgeries. Utilizing this unprecedented CINM modality, in conjunction with localized neurostimulation, we further demonstrated our approach in enabling optimal post-operative prognosis in preclinical animal models by preserving normal neural functions after a variety of tumor resection surgeries.
Publisher
Cold Spring Harbor Laboratory