An adaptive semi‐implicit finite element solver for brain cancer progression modeling

Tzirakis, Konstantinos; Papanikas, Christos Panagiotis; Sakkalis, Vangelis; Tzamali, Eleftheria; Papaharilaou, Yannis; Caiazzo, Alfonso; Stylianopoulos, Triantafyllos; Vavourakis, Vasileios

doi:10.1002/cnm.3734

Numer Methods Biomed Eng

2023

DOI: 10.1002/cnm.3734

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An adaptive semi‐implicit finite element solver for brain cancer progression modeling

Konstantinos Tzirakis

Christos Panagiotis Papanikas

Vangelis Sakkalis

et al.

Abstract: Glioblastoma is the most aggressive and infiltrative glioma, classified as Grade IV, with the poorest survival rate among patients. Accurate and rigorously tested mechanistic in silico modeling offers great value to understand and quantify the progression of primary brain tumors. This paper presents a continuum‐based finite element framework that is built on high performance computing, open‐source libraries to simulate glioblastoma progression. We adopt the established proliferation invasion hypoxia necrosis a… Show more

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Personalized optimization strategy for electrode array layout in TTFields of glioblastoma

Wang,

Chen,

Xiao

et al. 2024

Numer Methods Biomed Eng

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Tumor treating fields (TTFields) is a novel therapeutic approach for the treatment of glioblastoma. The electric field intensity is a critical factor in the therapeutic efficacy of TTFields, as stronger electric field can more effectively impede the proliferation and survival of tumor cells. In this study, we aimed to improve the therapeutic effectiveness of TTFields by optimizing the position of electrode arrays, resulting in an increased electric field intensity at the tumor. Three representative head models of real glioblastoma patients were used as the research subjects in this study. The improved subtraction‐average‐based optimization (ISABO) algorithm based on circle chaos mapping, opposition‐based learning and golden sine strategy, was employed to optimize the positions of the four sets of electrode arrays on the scalp. The electrode positions are dynamically adjusted through iterative search to maximize the electric field intensity at the tumor. The experimental results indicate that, in comparison to the conventional layout, the positions of the electrode arrays obtained by the ISABO algorithm can achieve average electric field intensity of 1.7887, 2.0058, and 1.3497 V/cm at the tumor of three glioblastoma patients, which are 23.6%, 29.4%, and 8.5% higher than the conventional layout, respectively. This study demonstrates that optimizing the location of the TTFields electrode array using the ISABO algorithm can effectively enhance the electric field intensity and treatment coverage in the tumor area, offering a more effective approach for personalized TTFields treatment.

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Personalized optimization strategy for electrode array layout in TTFields of glioblastoma

Wang,

Chen,

Xiao

et al. 2024

Numer Methods Biomed Eng

View full text Add to dashboard Cite

show abstract

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An adaptive semi‐implicit finite element solver for brain cancer progression modeling

Cited by 1 publication

References 49 publications

Personalized optimization strategy for electrode array layout in TTFields of glioblastoma

Personalized optimization strategy for electrode array layout in TTFields of glioblastoma

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