AMBER:肿瘤生长、血管和辐射反应模块化模型。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-26 DOI:10.1007/s11538-024-01371-4
Louis V Kunz, Jesús J Bosque, Mohammad Nikmaneshi, Ibrahim Chamseddine, Lance L Munn, Jan Schuemann, Harald Paganetti, Alejandro Bertolet
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引用次数: 0

摘要

肿瘤生长的计算模型对于模拟癌症进展和治疗反应的动态非常有价值。尤其是跟踪单个病原体及其相互作用的基于病原体的模型(ABM),因其灵活性和模拟复杂行为的能力而非常有用。然而,ABM 通常局限于小领域,或者在扩大规模时忽略了血管等关键方面。此外,使用黄金标准蒙特卡洛(Monte Carlo,MC)方法将精确的辐射剂量计算整合到肿瘤 ABM 中,这在当代放射治疗中至关重要,但一直缺乏这种整合。在此,我们介绍一种基于代理的放射生物效应放疗模型(AMBER),它能对肿瘤生长和放射反应进行计算建模。AMBER 基于体素化的几何结构,通过逐步追踪时间上的离散状态,在相关临床前尺度上实现了逼真的模拟。其混合方法将传统的 ABM 技术与氧气和血管内皮生长因子等关键微环境因素的连续时空场相结合,有助于生成逼真的迂回血管树。此外,AMBER 还集成了 TOPAS,这是一种基于 MC 的粒子传输算法,可模拟异质辐射剂量。辐射对肿瘤动力学的影响考虑了改变辐射敏感性的微环境因素,如氧气的可用性,提供了生物和物理方面的全面耦合。我们的研究结果表明,使用 AMBER 进行的模拟能够产生准确的肿瘤演变和放射治疗结果,这与既定的体积生长规律和放射生物学认识是一致的。因此,AMBER 是复制肿瘤生长和辐射反应基本特征的一种很有前途的工具,它提供了一种模块化设计,可在未来扩展到特定的生物特征。
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AMBER: A Modular Model for Tumor Growth, Vasculature and Radiation Response.

Computational models of tumor growth are valuable for simulating the dynamics of cancer progression and treatment responses. In particular, agent-based models (ABMs) tracking individual agents and their interactions are useful for their flexibility and ability to model complex behaviors. However, ABMs have often been confined to small domains or, when scaled up, have neglected crucial aspects like vasculature. Additionally, the integration into tumor ABMs of precise radiation dose calculations using gold-standard Monte Carlo (MC) methods, crucial in contemporary radiotherapy, has been lacking. Here, we introduce AMBER, an Agent-based fraMework for radioBiological Effects in Radiotherapy that computationally models tumor growth and radiation responses. AMBER is based on a voxelized geometry, enabling realistic simulations at relevant pre-clinical scales by tracking temporally discrete states stepwise. Its hybrid approach, combining traditional ABM techniques with continuous spatiotemporal fields of key microenvironmental factors such as oxygen and vascular endothelial growth factor, facilitates the generation of realistic tortuous vascular trees. Moreover, AMBER is integrated with TOPAS, an MC-based particle transport algorithm that simulates heterogeneous radiation doses. The impact of radiation on tumor dynamics considers the microenvironmental factors that alter radiosensitivity, such as oxygen availability, providing a full coupling between the biological and physical aspects. Our results show that simulations with AMBER yield accurate tumor evolution and radiation treatment outcomes, consistent with established volumetric growth laws and radiobiological understanding. Thus, AMBER emerges as a promising tool for replicating essential features of tumor growth and radiation response, offering a modular design for future expansions to incorporate specific biological traits.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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