化学激活的发光蛋白使光遗传学能够抑制癫痫网络中的分布式节点,从而实现非侵入性和多部位的癫痫活动抑制。
Chemically activated luminopsins allow optogenetic inhibition of distributed nodes in an epileptic network for non-invasive and multi-site suppression of seizure activity.
机构信息
Coulter Department of Biomedical Engineering, Georgia Institute of Technology, Atlanta, GA, United States; Department of Neurosurgery, Emory University School of Medicine, Atlanta, GA, United States.
Department of Neurosurgery, Emory University School of Medicine, Atlanta, GA, United States.
出版信息
Neurobiol Dis. 2018 Jan;109(Pt A):1-10. doi: 10.1016/j.nbd.2017.09.007. Epub 2017 Sep 18.
Abstract
Although optogenetic techniques have proven to be invaluable for manipulating and understanding complex neural dynamics over the past decade, they still face practical and translational challenges in targeting networks involving multiple, large, or difficult-to-illuminate areas of the brain. We utilized inhibitory luminopsins to simultaneously inhibit the dentate gyrus and anterior nucleus of the thalamus of the rat brain in a hardware-independent and cell-type specific manner. This approach was more effective at suppressing behavioral seizures than inhibition of the individual structures in a rat model of epilepsy. In addition to elucidating mechanisms of seizure suppression never directly demonstrated before, this work also illustrates how precise multi-focal control of pathological circuits can be advantageous for the treatment and understanding of disorders involving broad neural circuits such as epilepsy.
摘要
尽管在过去十年中,光遗传学技术已被证明对于操作和理解复杂的神经动力学非常有价值,但在针对涉及多个、大的或难以照明的脑区的网络时,它们仍然面临实际和转化方面的挑战。我们利用抑制性发光蛋白以硬件独立和细胞类型特异性的方式同时抑制大鼠大脑的齿状回和丘脑前核。与抑制癫痫大鼠模型中单个结构相比,这种方法更有效地抑制了行为性癫痫发作。除了阐明以前从未直接证明的癫痫发作抑制机制外,这项工作还说明了精确的多焦点病理性回路控制如何有利于治疗和理解涉及广泛神经回路的疾病,如癫痫。
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