Biomedical applications of nanoscale tools and nano-bio interface: A blueprint of physical, chemical, and biochemical cues of cell mechanotransduction machinery

R. Kumar
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引用次数: 1

Abstract

A dream to have control over the cell behavior by nanoscale tools and nano-bio interface to mimic remodeling of cell mechanotransduction machinery, is an updated approach and the latest theme of current research.[1] To achieve such a goal, the nanofabrication technique plays a key role in designing novel nanoscale tools capable of stimulating the natural extracellular matrix (ECM). These nano-bio tools can create a valuable nanoscale interface, and finally, these advanced tools control cell behavior. Structurally and compositionally, the cells are too complicated and well equipped with remarkable features. It has a lot of complexity in it. The initial hurdle is the natural composition of cells and the surroundings of the nanoscale. The cell is too complicated, and it is a difficult and tough task to determine the features of its areas. The emergence of nanoscale tools, which are capable of analyzing and performing by applying single-molecule with high precision is helping for boosting cellular events for enhancing biomedical claims.[2] These tools and biomedical methods consist of nanomaterials that can perform as nanodevices, expose the cellular environment and simulate the cell-matrix interface. These biomedical methods are now considered major outfits for further analysis. [3] To detect the surface patterning of the cells and concerned topographies of cellular environments, these nanoscale devices, and 3D microporous scaffolds derived from nanomaterials are the main equipment applied to exploit the hidden areas and undiscovered activities of the cell components.
纳米尺度工具和纳米生物界面的生物医学应用:细胞机械转导机制的物理、化学和生物化学线索蓝图
通过纳米尺度工具和纳米生物界面来控制细胞行为,以模拟细胞机械转导机制的重塑,这是一种更新的方法,也是当前研究的最新主题。[1] 为了实现这一目标,纳米制造技术在设计能够刺激天然细胞外基质(ECM)的新型纳米级工具方面发挥着关键作用。这些纳米生物工具可以创造一个有价值的纳米级界面,最终,这些先进的工具可以控制细胞行为。从结构和组成上看,细胞过于复杂,具有显著的特征。它有很多复杂性。最初的障碍是细胞的自然组成和纳米级的环境。细胞太复杂了,确定其区域的特征是一项困难而艰巨的任务。纳米级工具的出现,能够通过高精度应用单分子进行分析和执行,有助于促进细胞事件,以增强生物医学声明。[2] 这些工具和生物医学方法由纳米材料组成,可以作为纳米设备,暴露细胞环境并模拟细胞-基质界面。这些生物医学方法现在被认为是进一步分析的主要工具。[3] 为了检测细胞的表面图案和细胞环境的相关拓扑图,这些纳米级设备和衍生自纳米材料的3D微孔支架是用于开发细胞成分的隐藏区域和未发现的活性的主要设备。
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