石墨烯纳米结构对细胞骨架偶联抗肿瘤转移的尺寸效应

Smart medicine Pub Date : 2023-08-03 eCollection Date: 2023-08-01 DOI:10.1002/SMMD.20230014
Qiqige Du, Na Li, Jiaqi Lian, Jun Guo, Yi Zhang, Feng Zhang
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引用次数: 0

摘要

无机材料和生命系统之间的相互作用可能受到材料的尺寸特性的强烈影响,这反过来又会影响生物活动。虽然生物材料在分子和细胞尺度上的作用已经被研究过,但对生物材料在多维尺度上的作用的研究相对较少。在此,我们比较了二维氧化石墨烯纳米片(go)和三维氧化石墨烯量子点(GOQDs)(虽然不是零维的,因为它们的表面积很大)在癌症治疗中的有效性,我们发现,在相同的质量浓度下,go比GOQDs表现出更强的抗癌和抗肿瘤转移特性。我们的研究采用液相原子力显微镜,揭示了低维go创造了一个更广泛的纳米生物界面,阻碍肌动蛋白聚合到细胞骨架中,从而防止肿瘤转移。这些结果有助于更好地理解潜在的机制,并为优化石墨烯基材料的性能提供了一个维度的视角,用于临床应用,例如癌症治疗。
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Dimensional effect of graphene nanostructures on cytoskeleton-coupled anti-tumor metastasis.

Interactions between inorganic materials and living systems can be strongly influenced by the dimensional property of the materials, which can in turn impact biological activities. Although the role of biomaterials at the molecular and cellular scales has been studied, research investigating the effects of biomaterials across multiple dimensional scales is relatively scarce. Herein, comparing the effectiveness of two-dimensional graphene oxide nanosheets (GOs) and three-dimensional graphene oxide quantum dots (GOQDs) (though not zero-dimensional because of their significant surface area) in cancer therapies, we have discovered that GOs, with the same mass concentration, exhibit stronger anti-cancer and anti-tumor metastasis properties than GOQDs. Our research, which employed liquid-phase atomic force microscopy, revealed that lower-dimensional GOs create a more extensive nano-bio interface that impedes actin protein polymerization into the cytoskeleton, leading to the prevention of tumor metastasis. These results help to better understand the underlying mechanisms and offer a dimensional perspective on the potential of optimizing the properties of graphene-based materials for clinical applications, e.g., cancer therapy.

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