Predicting the Progression of Cancerous Tumors in Mice: A Machine and Deep Learning Intuition

Amit K Chattopadhyay, Aimee Pascaline N Unkundiye, Gillian Pearce, Steven Russell
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Abstract

The study explores Artificial Intelligence (AI) powered modeling to predict the evolution of cancer tumor cells in mice under different forms of treatment. The AI models are analyzed against varying ambient and systemic parameters, e.g. drug dosage, volume of the cancer cell mass, and time taken to destroy the cancer cell mass. The data required for the analysis have been synthetically extracted from plots available in both published and unpublished literature (primarily using a Matlab architecture called "Grabit"), that are then statistically standardized around the same baseline for comparison. Three forms of treatment are considered - saline (multiple concentrations used), magnetic nanoparticles (mNPs) and fluorodeoxyglycose iron oxide magnetic nanoparticles (mNP-FDGs) - analyzed using three Machine Learning (ML) algorithms, Decision Tree (DT), Random Forest (RF), Multilinear Regression (MLR), and a Deep Learning (DL) module, the Adaptive Neural Network (ANN). The AI models are trained on 60-80% data, the rest used for validation. Assessed over all three forms of treatment, ANN consistently outperforms other predictive models. Our models predict mNP-FDG as the most potent treatment regime that kills the cancerous tumor completely in ca 13 days from the start of treatment. The models can be generalized to other forms of cancer treatment regimens.
预测小鼠癌症肿瘤的进展:一种机器和深度学习直觉
该研究探索了以人工智能(AI)为动力的建模方法,以预测不同治疗方式下小鼠体内癌症肿瘤细胞的演变过程。人工智能模型根据不同的环境和系统参数(如药物剂量、癌细胞体积和消灭癌细胞所需的时间)进行分析。分析所需的数据是从已发表和未发表的文献(主要使用名为 "Grabit "的 Matlab 架构)中合成提取的。考虑了三种治疗形式--生理盐水(使用多种浓度)、磁性纳米粒子(mNPs)和氟脱氧甘糖氧化铁磁性纳米粒子(mNP-FDGs)--使用三种机器学习(ML)算法进行分析:决策树(DT)、随机森林(RF)、多线性回归(MLR)和深度学习(DL)模块--自适应神经网络(ANN)。人工智能模型在 60-80% 的数据上进行训练,其余数据用于验证。在所有三种形式的治疗中,ANN 的表现始终优于其他预测模型。我们的模型预测 mNP-FDG 是最有效的治疗方案,能在治疗开始后的 13 天内完全杀死癌肿瘤。这些模型可以推广到其他形式的癌症治疗方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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