Yawer H. Shah, Luigi Palatella, Korosh Mahmoodi, Orazio S. Santonocito, Mariangela Morelli, Gianmarco Ferri, Chiara M. Mazzanti, Paolo Grigolini, Bruce J. West
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引用次数: 0
摘要
本文受列维随机漫步的启发,分析了胶质母细胞瘤(GB)细胞的运动及其建模。我们研究的是发生在二维平面上的随机行走,这种行走类似于鸟类的匀速直线飞行,但在飞行过程中会随机改变方向。鸟的智能通过飞行方向的瞬时变化来体现,而这种变化在将二维行走投影到 x 轴或 y 轴后得到的时间序列中是不可见的。我们发现,投影的一维时间序列与常用来监测生理过程的时间序列具有相同的统计复杂性,从而揭示了关键事件(CE-s)在病理生理学中的作用。这种关键事件的标志是飞行方向的突然改变,而这种改变在一维生理时间序列中是不可见的。我们通过 \mu_{R} = 2 - \delta 建立了由 CE-sthrough 生成的复缩放指数 \delta 之间的联系,其中 \mu_{R} 是相关过程连续失败之间时间间隔的概率密度函数的反幂律指数。我们认为,经验指数的确定及其理论关系为控制癌症提供了重要措施。
Cell Motility in Cancer, Crucial Events, Criticality, and Lévy Walks
The analysis of glioblastoma (GB) cell locomotion and its modeling inspired
by Levy random walks is presented herein. We study such walks occurring on a
two-dimensional plane where the walk is similar to the motion of a bird flying
with a constant velocity, but with random changes of direction in time. The
intelligence of the bird is signaled by the instantaneous changes of flying
direction, which become invisible in the time series obtained by projecting the
2D walk either on the x axis or the y axis. We establish that the projected 1D
time series share the statistical complexity of time series frequently used to
monitor physiological processes, shedding light on the role of crucial events
(CE-s) in pathophysiology. Such CE-s are signified by abrupt changes of flying
direction which are invisible in the 1D physiological time series. We establish
a connection between the complex scaling index \delta generated by the CE-s
through \mu_{R} = 2 - \delta , where \mu_{R} is the inverse power law index of
the probability density function of the time interval between consecutive
failures of the process of interest. We argue that the identification of
empirical indices along with their theoretical relations afford important
measures to control cancer.