Gregory Girardi, Danielle Zumpano, Helen Raybould, Erkin Seker
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We show that this microfluidic model successfully compartmentalizes the cell body and neurite terminals of the neurons, thereby simulates the anatomical layout of these neurons to more accurately study physiologically-relevant processes.</p><p><strong>Methods: </strong>We implemented a primary rat vagal afferent neuron culture into a microfluidic platform consisting of two concentric chambers interconnected with radial microchannels. The microfluidic platform separated cell bodies from neurite terminals of vagal afferent neurons. We then introduced physiologically-relevant gastrointestinal effector molecules at the nerve terminals and assessed their retrograde transport along the neurite or capacity to elicit an electrophysiological response using live cell calcium imaging.</p><p><strong>Results: </strong>The angle of microchannel outlets dictated the probability of neurites growing into a chamber versus tracking along chamber walls. When the neurite terminals were exposed to fluorescently-labeled cholera toxin subunit B, the proteins were taken up and retrogradely transported along the neurites over the course of 24 h. Additionally, mechanical perturbation (e.g., rinsing) of the neurite terminals significantly increased intracellular calcium concentration in the distal soma. Finally, membrane-displayed receptor for capsaicin was expressed and trafficked along newly projected neurites, as revealed by confocal microscopy.</p><p><strong>Conclusions: </strong>In this work, we developed a microfluidic device that can recapitulate the anatomical layout of vagal afferent neurons in vitro. We demonstrated two physiologically-relevant applications of the platforms: retrograde transport and electrophysiological response. 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引用次数: 0
摘要
背景:迷走传入神经元代表了肠-脑轴的关键神经感觉分支,它描述了胃肠道系统与大脑之间的双向交流。这些神经元对于检测和将外周的感觉信息传递到中枢神经系统以调节进食行为、新陈代谢和炎症非常重要。混杂的变量使分离迷走神经传入在介导这些生理过程中的作用的过程变得更加复杂。因此,我们开发了一种肠脑轴感觉分支的微流控模型。我们的研究表明,该微流体模型成功地将神经元的细胞体和神经末梢分隔开来,从而模拟了这些神经元的解剖布局,更准确地研究了生理相关过程:方法:我们将原代大鼠迷走传入神经元培养物放入一个微流控平台中,该平台由两个同心腔组成,并通过径向微通道相互连接。微流控平台将迷走传入神经元的细胞体与神经末梢分开。然后,我们在神经末梢引入了与生理相关的胃肠道效应分子,并利用活细胞钙成像技术评估了它们沿神经元逆行运输或引起电生理反应的能力:微通道出口的角度决定了神经元长入腔室与沿腔室壁追踪的概率。当神经元末端暴露于荧光标记的霍乱毒素亚单位 B 时,蛋白质被吸收并在 24 小时内沿着神经元逆向运输。此外,神经元末端的机械扰动(如冲洗)会显著增加远端体细胞内的钙浓度。最后,共聚焦显微镜显示,膜显示的辣椒素受体沿着新突起的神经元表达和迁移:在这项工作中,我们开发了一种微流控装置,可以在体外再现迷走神经传入神经元的解剖布局。我们展示了该平台的两个生理相关应用:逆行运输和电生理反应。我们希望这一工具能帮助我们对迷走传入神经元在肠脑轴中的作用进行对照研究。
Microfluidic compartmentalization of rat vagal afferent neurons to model gut-brain axis.
Background: Vagal afferent neurons represent the key neurosensory branch of the gut-brain axis, which describes the bidirectional communication between the gastrointestinal system and the brain. These neurons are important for detecting and relaying sensory information from the periphery to the central nervous system to modulate feeding behavior, metabolism, and inflammation. Confounding variables complicate the process of isolating the role of the vagal afferents in mediating these physiological processes. Therefore, we developed a microfluidic model of the sensory branch of the gut-brain axis. We show that this microfluidic model successfully compartmentalizes the cell body and neurite terminals of the neurons, thereby simulates the anatomical layout of these neurons to more accurately study physiologically-relevant processes.
Methods: We implemented a primary rat vagal afferent neuron culture into a microfluidic platform consisting of two concentric chambers interconnected with radial microchannels. The microfluidic platform separated cell bodies from neurite terminals of vagal afferent neurons. We then introduced physiologically-relevant gastrointestinal effector molecules at the nerve terminals and assessed their retrograde transport along the neurite or capacity to elicit an electrophysiological response using live cell calcium imaging.
Results: The angle of microchannel outlets dictated the probability of neurites growing into a chamber versus tracking along chamber walls. When the neurite terminals were exposed to fluorescently-labeled cholera toxin subunit B, the proteins were taken up and retrogradely transported along the neurites over the course of 24 h. Additionally, mechanical perturbation (e.g., rinsing) of the neurite terminals significantly increased intracellular calcium concentration in the distal soma. Finally, membrane-displayed receptor for capsaicin was expressed and trafficked along newly projected neurites, as revealed by confocal microscopy.
Conclusions: In this work, we developed a microfluidic device that can recapitulate the anatomical layout of vagal afferent neurons in vitro. We demonstrated two physiologically-relevant applications of the platforms: retrograde transport and electrophysiological response. We expect this tool to enable controlled studies on the role of vagal afferent neurons in the gut-brain axis.