利用氧传感器检测纳米地貌诱导的细胞迁移方向变化

Biosensors Pub Date : 2024-08-12 DOI:10.3390/bios14080389
Muting Wang, Stella W. Pang
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引用次数: 0

摘要

这项研究调查了单细胞在迁移方向变化过程中的氧气(O2)消耗情况。这是首次将纳米光斑与氧气生物传感器集成在一个平台上,从而能够实时监测细胞的氧气消耗量,并区分向同一方向迁移的细胞和向相反方向迁移的细胞。研究人员利用先进的纳米制造技术在光栅脊上图案化纳米孔或纳米柱,并利用荧光显微镜、细胞迁移实验和氧气消耗分析评估了它们的效果。结果显示,光栅脊上的纳米柱上的细胞表现出更强的迁移运动性和更频繁的方向变化。此外,这些细胞的突起和丝状体数量增加,F-肌动蛋白区域更加密集,纳米柱周围的点状F-肌动蛋白结构数量增加。动态新陈代谢反应也很明显,八乙基卟啉酮铂染料的荧光强度峰值表明,由于响应方向变化所需的能量较高,O2 消耗增加,线粒体活性提高。这项研究强调了氧气消耗与细胞迁移方向变化之间复杂的相互作用,为生物材料科学和再生医学提供了启示。研究提出了引导细胞迁移和新陈代谢的生物材料的创新设计,提倡利用纳米工程平台,将细胞与其微环境之间错综复杂的关系用于治疗应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Detecting Nanotopography Induced Changes in Cell Migration Directions Using Oxygen Sensors
This study investigates the oxygen (O2) consumption of single cells during changes in their migration direction. This is the first integration of nanotopographies with an O2 biosensor in a platform, allowing the real-time monitoring of O2 consumption in cells and the ability to distinguish cells migrating in the same direction from those migrating in the opposite direction. Advanced nanofabrication technologies were used to pattern nanoholes or nanopillars on grating ridges, and their effects were evaluated using fluorescence microscopy, cell migration assays, and O2 consumption analysis. The results revealed that cells on the nanopillars over grating ridges exhibited an enhanced migration motility and more frequent directional changes. Additionally, these cells showed an increased number of protrusions and filopodia with denser F-actin areas and an increased number of dotted F-actin structures around the nanopillars. Dynamic metabolic responses were also evident, as indicated by the fluorescence intensity peaks of platinum octaethylporphyrin ketone dye, reflecting an increased O2 consumption and higher mitochondria activities, due to the higher energy required in response to directional changes. The study emphasizes the complex interplay between O2 consumption and cell migration directional changes, providing insights into biomaterial science and regenerative medicine. It suggests innovative designs for biomaterials that guide cell migration and metabolism, advocating nanoengineered platforms to harness the intricate relationships between cells and their microenvironments for therapeutic applications.
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