Yuri G. Vilela, Artur C. Fassoni, Armando G. M. Neves
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However,\nalgorithms for cycle design, the conditions on which such algorithms are\ncertain to work, as well as conditions for cycle stability remain elusive.\nHere, we state biologically motivated hypotheses that guarantee existence of\nsuch cycles in two deterministic classes of mathematical models already\nconsidered in the literature: Lotka-Volterra and adjusted replicator dynamics.\nWe stress that not only existence of cyclic schemes, but also stability of such\ncycles is a relevant feature for applications in real clinical scenarios. We\nalso analyze stochastic versions of the above deterministic models, a necessary\nstep if we want to take into account that real tumors are composed by a finite\npopulation of cells subject to randomness, a relevant feature in the context of\nlow tumor burden. We argue that the stability of the deterministic cycles is\nalso relevant for the stochastic version of the models. In fact, Dua, Ma and\nNewton [Cancers (2021)] and Park and Newton [Phys. 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引用次数: 0
摘要
适应性疗法是治疗癌症的一种有前途的模式,它利用药物敏感细胞和耐药细胞之间的竞争性相互作用,从而避免或延缓因肿瘤内耐药性演变而导致的治疗失败。以往的研究表明,在数学上可以建立循环给药方案,在确定性模型中将肿瘤成分恢复到精确的初始值。然而,循环设计的算法、这种算法确定有效的条件以及循环稳定性的条件仍然难以捉摸。在这里,我们提出了以生物学为动机的假设,以保证在文献中已经考虑过的两类确定性数学模型中存在这种循环:我们强调,不仅循环方案存在,而且这种循环的稳定性也是实际临床应用的一个相关特征。我们还分析了上述确定性模型的随机版本,如果我们想考虑到真实肿瘤是由受随机性影响的有限细胞群组成,这是一个必要的步骤。我们认为,确定性循环的稳定性也与随机模型有关。事实上,Dua、Ma 和 Newton [Cancers (2021)]以及 Park 和 Newton [Phys. Rev. E (2023)]在肿瘤的随机模型(莫伦过程)中观察到了确定性循环的崩溃。我们的研究结果表明,这种崩溃现象不是由于随机性本身,而是由于参考文献中的循环所固有的确定性不稳定性。然后,我们说明了稳定的确定性循环如何在很大程度上避免随机肿瘤模型循环处理的崩溃。
On the design and stability of cancer adaptive therapy cycles: deterministic and stochastic models
Adaptive therapy is a promising paradigm for treating cancers, that exploits
competitive interactions between drug-sensitive and drug-resistant cells,
thereby avoiding or delaying treatment failure due to evolution of drug
resistance within the tumor. Previous studies have shown the mathematical
possibility of building cyclic schemes of drug administration which restore
tumor composition to its exact initial value in deterministic models. However,
algorithms for cycle design, the conditions on which such algorithms are
certain to work, as well as conditions for cycle stability remain elusive.
Here, we state biologically motivated hypotheses that guarantee existence of
such cycles in two deterministic classes of mathematical models already
considered in the literature: Lotka-Volterra and adjusted replicator dynamics.
We stress that not only existence of cyclic schemes, but also stability of such
cycles is a relevant feature for applications in real clinical scenarios. We
also analyze stochastic versions of the above deterministic models, a necessary
step if we want to take into account that real tumors are composed by a finite
population of cells subject to randomness, a relevant feature in the context of
low tumor burden. We argue that the stability of the deterministic cycles is
also relevant for the stochastic version of the models. In fact, Dua, Ma and
Newton [Cancers (2021)] and Park and Newton [Phys. Rev. E (2023)] observed
breakdown of deterministic cycles in a stochastic model (Moran process) for a
tumor. Our findings indicate that the breakdown phenomenon is not due to
stochasticity itself, but to the deterministic instability inherent in the
cycles of the referenced papers. We then illustrate how stable deterministic
cycles avoid for very large times the breakdown of cyclic treatments in
stochastic tumor models.