Oriented artificial nanofibers and laser induced periodic surface structures as substrates for Schwann cells alignment.

Open research Europe Pub Date : 2024-10-22 eCollection Date: 2024-01-01 DOI:10.12688/openreseurope.17370.3
Sebastian Lifka, Cristina Plamadeala, Agnes Weth, Johannes Heitz, Werner Baumgartner
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Abstract

People with injuries to the peripheral nervous system suffer from paralysis of the facial muscles, fingers and hands or toes and feet, often for the rest of their lives, due to its poor functional regeneration. Therefore, to improve patients' quality of life, there is an urgent need for conduits that effectively support the healing of large defects in nerve pathways through specific guidance of nerve cells. This paper describes two specific methods for achieving directed growth of Schwann cells, a type of glial cells that can support the regeneration of the nerve pathway by guiding the neuronal axons in the direction of their alignment. One method uses aligned polyamide-6 (PA-6) nanofibers produced via electrospinning on a very fast rotating structured collector, which enables easy nanofiber detachment, without additional effort. The other method implies the exposure of a poly(ethylene terephthalate) (PET) foil to a KrF* laser beam, that renders a nanorippled surface topography. Schwann cell growth on these substrates was inspected after one week of cultivation by means of scanning electron microscopy (SEM). For both methods we show that Schwann cells grow in a certain direction, predetermined by nanofiber and nanoripple orientation. In contrast, cells cultivated on randomly oriented nanofibers or unstructured surfaces, show an omnidirectional growth behavior. These two methods can be used to produce nerve conduits for the treatment of injuries to the peripheral nervous system.

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定向人造纳米纤维和激光诱导周期性表面结构作为许旺细胞排列的基底。
周围神经系统受伤的人,由于其功能再生能力差,面部肌肉、手指和手掌或脚趾和脚掌往往会终生瘫痪。因此,为了提高患者的生活质量,迫切需要一种导管,通过对神经细胞的特定引导,有效支持神经通路大面积缺损的愈合。许旺细胞是一种胶质细胞,可通过引导神经轴突的排列方向支持神经通路的再生。其中一种方法使用的是在快速旋转的结构收集器上通过电纺丝产生的排列整齐的聚酰胺-6(PA-6)纳米纤维,这种收集器可使纳米纤维轻松脱离,无需额外的努力。另一种方法是将聚对苯二甲酸乙二醇酯(PET)箔暴露于 KrF* 激光束中,从而形成纳米波纹表面形貌。通过扫描电子显微镜(SEM)对这些基底上的许旺细胞在培养一周后的生长情况进行了检测。我们发现,这两种方法都能使许旺细胞按照纳米纤维和纳米波纹的方向生长。相反,在随机定向的纳米纤维或非结构化表面上培养的细胞则表现出全方位的生长行为。这两种方法可用于生产神经导管,用于治疗外周神经系统损伤。
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