A multi-objective optimization framework for determining optimal chemotherapy dosing and treatment duration

Ismail Abdulrashid , Dursun Delen , Basiru Usman , Mark Izuchukwu Uzochukwu , Idris Ahmed
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引用次数: 0

Abstract

Traditional randomized clinical trials are regarded as the gold standard for assessing the efficacy of chemotherapy. However, this procedure has drawbacks such as high cost, time consumption, and limited patient exploration of treatment regimens. We develop a multi-objective optimization-based framework to address these limitations and determine the best chemotherapy dosing and treatment duration. The proposed framework uses patient-specific biological parameters to create a mathematical model of cell population dynamics in the patient’s body. The framework employs evolutionary heuristic search methods (simulated annealing and genetic algorithms) and a prescriptive analytics approach to optimize therapy sessions that transition from treatment to relaxation. We carefully adjust the chemotherapy dose during treatment to reduce tumor cells while preserving host cells (such as effector-immune cells). We strategically time the relaxation sessions to aid recovery, considering the ability of tumors and healthy cells to regenerate. We use a combined optimization method to determine the length of the session and the amount of drug to be administered. We compare quadratic and linear optimal control solvers for drug administration while genetic algorithms and simulated annealing are used to optimize session length. This approach is especially important in limited healthcare resources, ensuring efficient allocation while accurately identifying high-risk patients to optimize resource allocation and utilization.

确定最佳化疗剂量和疗程的多目标优化框架
传统的随机临床试验被视为评估化疗疗效的黄金标准。然而,这种方法存在成本高、耗时长、患者对治疗方案的探索有限等缺点。我们开发了一种基于多目标优化的框架来解决这些局限性,并确定最佳化疗剂量和疗程。所提出的框架使用患者特定的生物参数来创建患者体内细胞群动态的数学模型。该框架采用进化启发式搜索方法(模拟退火和遗传算法)和规范分析方法来优化从治疗过渡到放松的治疗疗程。我们在治疗过程中仔细调整化疗剂量,在减少肿瘤细胞的同时保留宿主细胞(如效应免疫细胞)。考虑到肿瘤和健康细胞的再生能力,我们有策略地安排放松疗程的时间,以帮助患者康复。我们采用综合优化方法来确定疗程的长度和给药量。我们比较了用于给药的二次方和线性优化控制求解器,同时使用遗传算法和模拟退火来优化疗程长度。在医疗资源有限的情况下,这种方法尤为重要,既能确保高效分配,又能准确识别高风险患者,从而优化资源分配和利用。
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来源期刊
Healthcare analytics (New York, N.Y.)
Healthcare analytics (New York, N.Y.) Applied Mathematics, Modelling and Simulation, Nursing and Health Professions (General)
CiteScore
4.40
自引率
0.00%
发文量
0
审稿时长
79 days
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