[Study on the mesoscopic dynamic effects of tumor treating fields on cell tubulin].

Q4 Medicine
Xing Li, Kaida Liu, Cong Guo, Tianrui Fang, Fan Yang
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引用次数: 0

Abstract

Tumor treatment fields (TTFields) can effectively inhibit the proliferation of tumor cells, but its mechanism remains exclusive. The destruction of cellular microtubule structure caused by TTFields through electric field force is considered to be the main reason for inhibiting tumor cell proliferation. However, the validity of this hypothesis still lacks exploration at the mesoscopic level. Therefore, in this study, we built force models for tubulins subjected to TTFields, based on the physical and electrical properties of tubulin molecules. We theoretically analyzed and simulated the dynamic effects of electric field force and torque on tubulin monomer polymerization, as well as the alignment and orientation of α/β tubulin heterodimer, respectively. Research results indicate that the interference of electric field force induced by TTFields on tubulin monomer is notably weaker than the inherent electrostatic binding force among tubulin monomers. Additionally, the electric field torque generated by the TTFileds on α/β tubulin dimers is also difficult to affect their random alignment. Therefore, at the mesoscale, our study affirms that TTFields are improbable to destabilize cellular microtubule structures via electric field dynamics effects. These results challenge the traditional view that TTFields destroy the microtubule structure of cells through TTFields electric field force, and proposes a new approach that should pay more attention to the "non-mechanical" effects of TTFields in the study of TTFields mechanism. This study can provide reliable theoretical basis and inspire new research directions for revealing the mesoscopic bioelectrical mechanism of TTFields.

[肿瘤治疗场对细胞微管蛋白的介观动态效应研究]。
肿瘤治疗场(TTFields)能有效抑制肿瘤细胞的增殖,但其机制尚不明确。肿瘤治疗场通过电场力破坏细胞微管结构被认为是抑制肿瘤细胞增殖的主要原因。然而,这一假说的有效性仍缺乏中观层面的探讨。因此,在本研究中,我们根据微管蛋白分子的物理和电学特性,建立了微管蛋白在TTFields作用下的受力模型。我们分别从理论上分析和模拟了电场力和力矩对微管蛋白单体聚合以及α/β微管蛋白异源二聚体排列和取向的动态影响。研究结果表明,TTFields 诱导的电场力对微管蛋白单体的干扰明显弱于微管蛋白单体间固有的静电结合力。此外,TTFileds 在 α/β 管蛋白二聚体上产生的电场力矩也难以影响它们的随机排列。因此,我们的研究证实,在中尺度上,TTFields 不可能通过电场动力学效应破坏细胞微管结构的稳定性。这些结果对传统的TTFields通过TTFields电场力破坏细胞微管结构的观点提出了挑战,并提出了一种新的方法,即在研究TTFields机制时应更多地关注TTFields的 "非机械 "效应。该研究为揭示TTFields的介观生物电机制提供了可靠的理论依据和新的研究方向。
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来源期刊
生物医学工程学杂志
生物医学工程学杂志 Medicine-Medicine (all)
CiteScore
0.80
自引率
0.00%
发文量
4868
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