c-Fos immunoreactivity and variation of neuronal units in rat's motor cortex after chronic implants

M. Freire, J. Faber, J. R. Santos, Nelson A. M. Lemos, M. A. Aratanha, Pedro F. Cavalcanti, E. Morya
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引用次数: 2

Abstract

Recovering of people suffering from spinal cord and brain lesion is a medical challenge. Brain-machine interface (BMI) emerges as a potential candidate, by allowing patients to use their own brain activity to reestablish sensorimotor control of paralyzed body parts. BMI can be divided in two main groups: non-invasive, based in the capture of the neuronal signal over the cranium, and invasive, much more effective in generating high resolution brain-derived motor control signals, despite requiring a brain surgery for implantation of recording microelectrodes. Accordingly, chronic multielectrodes implants define the fundamental component of an invasive BMI. However, it is important to characterize the impact of microwire arrays' implant on the nervous tissue before this technique can be available to human clinical trials. Here we evaluated the expression of immediate early-gene c-fos and inflammatory response (astrogliosis), as well as the quality of the neuronal signal comparing the variation of the total number and the amplitude of the recorded units after long-lasting chronic multielectrode implants. Electrode recordings remained viable for 6 months after implant, and did not alter the general physiology of the implanted tissue, as revealed by normal c-Fos expression in implanted sites. Moreover, there was a small inflammatory response across implanted regions. Our findings suggest that tungsten microwire arrays can be viable candidates to future human BMI interventions.
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慢性植入后大鼠运动皮质c-Fos免疫反应性及神经元单位的变化
脊髓和脑损伤患者的康复是一项医学挑战。脑机接口(BMI)是一种潜在的候选者,它允许患者使用自己的大脑活动来重建对瘫痪身体部位的感觉运动控制。BMI可以分为两大类:非侵入性,基于在头盖骨上捕获神经元信号;侵入性,尽管需要脑部手术植入记录微电极,但在产生高分辨率脑源性运动控制信号方面更有效。因此,慢性多电极植入定义了侵入性BMI的基本组成部分。然而,在该技术可用于人体临床试验之前,表征微线阵列植入对神经组织的影响是很重要的。在这里,我们评估了即时早期基因c-fos的表达和炎症反应(星形胶质细胞形成),以及神经元信号的质量,比较了长期慢性多电极植入后记录单位的总数和振幅的变化。电极记录在植入后6个月仍然有效,并且没有改变植入组织的一般生理机能,如植入部位正常的c-Fos表达所示。此外,整个植入区域都有轻微的炎症反应。我们的研究结果表明,钨微线阵列可以成为未来人类BMI干预的可行候选者。
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