Assessment of corneal nerve regeneration after axotomy in a compartmentalized microfluidic chip model with automated 3D high resolution live-imaging

IF 4.2 3区 医学 Q2 NEUROSCIENCES
N. Bonneau, A. Potey, Frédéric Blond, Camille Guerin, C. Baudouin, J. Peyrin, F. Brignole-Baudouin, A. Réaux-Le Goazigo
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Abstract

Damage to the corneal nerves can result in discomfort and chronic pain, profoundly impacting the quality of life of patients. Development of novel in vitro method is crucial to better understand corneal nerve regeneration and to find new treatments for the patients. Existing in vitro models often overlook the physiology of primary sensory neurons, for which the soma is separated from the nerve endings.To overcome this limitation, our novel model combines a compartmentalized microfluidic culture of trigeminal ganglion neurons from adult mice with live–imaging and automated 3D image analysis offering robust way to assess axonal regrowth after axotomy.Physical axotomy performed by a two-second aspiration led to a reproducible 70% axonal loss and altered the phenotype of the neurons, increasing the number of substance P-positive neurons 72 h post-axotomy. To validate our new model, we investigated axonal regeneration after exposure to pharmacological compounds. We selected various targets known to enhance or inhibit axonal regrowth and analyzed their basal expression in trigeminal ganglion cells by scRNAseq. NGF/GDNF, insulin, and Dooku-1 (Piezo1 antagonist) enhanced regrowth by 81, 74 and 157%, respectively, while Yoda-1 (Piezo1 agonist) had no effect. Furthermore, SARM1-IN-2 (Sarm1 inhibitor) inhibited axonal regrowth, leading to only 6% regrowth after 72 h of exposure (versus 34% regrowth without any compound).Combining compartmentalized trigeminal neuronal culture with advanced imaging and analysis allowed a thorough evaluation of the extent of the axotomy and subsequent axonal regrowth. This innovative approach holds great promise for advancing our understanding of corneal nerve injuries and regeneration and ultimately improving the quality of life for patients suffering from sensory abnormalities, and related conditions.
利用自动三维高分辨率实时成像技术,在分区微流控芯片模型中评估轴切断术后的角膜神经再生情况
角膜神经受损会导致不适和慢性疼痛,严重影响患者的生活质量。开发新型体外方法对于更好地了解角膜神经再生和为患者寻找新疗法至关重要。为了克服这一局限,我们的新型模型将成年小鼠三叉神经节神经元的分室微流控培养与实时成像和自动三维图像分析相结合,为评估轴突切断术后的轴突再生提供了可靠的方法。通过两秒钟的抽吸进行物理轴突切断,可重复地导致 70% 的轴突丢失,并改变了神经元的表型,增加了轴突切断后 72 小时 P 物质阳性神经元的数量。为了验证我们的新模型,我们研究了暴露于药理化合物后的轴突再生。我们选择了各种已知可促进或抑制轴突再生的靶点,并通过 scRNAseq 分析了它们在三叉神经节细胞中的基础表达。NGF/GDNF、胰岛素和Dooku-1(Piezo1拮抗剂)分别增强了轴突再生81%、74%和157%,而Yoda-1(Piezo1激动剂)则没有影响。此外,SARM1-IN-2(Sarm1 抑制剂)抑制轴突再生,在暴露 72 小时后仅有 6% 的轴突再生(而不使用任何化合物的情况下则有 34% 的轴突再生)。将三叉神经元分区培养与先进的成像和分析相结合,可以对轴突切断的程度和随后的轴突再生进行全面评估。这种创新方法有望促进我们对角膜神经损伤和再生的了解,并最终改善感觉异常和相关疾病患者的生活质量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.90
自引率
3.80%
发文量
627
审稿时长
6-12 weeks
期刊介绍: Frontiers in Cellular Neuroscience is a leading journal in its field, publishing rigorously peer-reviewed research that advances our understanding of the cellular mechanisms underlying cell function in the nervous system across all species. Specialty Chief Editors Egidio D‘Angelo at the University of Pavia and Christian Hansel at the University of Chicago are supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, clinicians and the public worldwide.
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