脑机接口的演进:动作电位、局部场电位和脑电描记图。
Evolution of brain-computer interface: action potentials, local field potentials and electrocorticograms.
机构信息
Washington University, Biomedical Engineering, 300F Whitaker Hall, One Brookings Drive Campus Box 1097, St. Louis, MO 63130, USA.
出版信息
Curr Opin Neurobiol. 2010 Dec;20(6):741-5. doi: 10.1016/j.conb.2010.09.010. Epub 2010 Oct 15.
Abstract
Brain computer interfaces (BCIs) were originally developed to give severely motor impaired patients a method to communicate and interact with their environment. Initially most BCI systems were based on non-invasive electroencephalographic recordings from the surface of the scalp. To increase control speed, accuracy and complexity, researchers began utilizing invasive recording modalities. BCIs using multi-single unit action potentials have provided elegant multi-dimensional control of both computer cursors and robotic limbs in the last few years. However, long-term stability issues with single-unit arrays has lead researchers to investigate other invasive recording modalities such as high-frequency local field potentials and electrocorticography (ECoG). Although ECoG originally evolved as a replacement for single-unit BCIs, it has come full circle to become an effective tool for studying cortical neurophysiology.
摘要
脑机接口(BCI)最初是为了给严重运动障碍的患者提供一种与环境进行交流和互动的方法而开发的。最初,大多数 BCI 系统都是基于从头皮表面进行的非侵入性脑电图记录。为了提高控制速度、准确性和复杂性,研究人员开始使用侵入性记录方式。在过去几年中,使用多单单元动作电位的 BCI 为计算机光标和机器人肢体的多维控制提供了优雅的控制。然而,单单元阵列的长期稳定性问题导致研究人员研究其他侵入性记录方式,如高频局部场电位和脑电描记术(ECoG)。尽管 ECoG 最初是作为单单元 BCI 的替代品发展起来的,但它已经回到了研究皮质神经生理学的有效工具。
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