Abstract 185: Monitoring of stem cell differentiation to mature hepatocytes with a machine learning-based AI model

Wei-Lei Yang, Zijun Huo, Shih‐Chen Chen, Dandan Zhu, Tien-Jen Liu, Dung-Fang Lee
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Abstract

Human embryonic stem cells (hESCs) and pluripotent stem cells (iPSCs)-based disease modelings are potential platforms for cancer research and development of new cancer therapeutics. Differentiation of stem cells is an essential step for those disease models. For tissue-specific differentiation, hESCs or iPSCs are cultured in specific receipts of induction and differentiation media for developing different types of tissue cells such as muscle, skin, and liver providing further study or clinical applications. During lineage differentiation, researcher needs to closely monitor stem cell differentiation to be on track via checking cell morphological changes under microscope since this procedure has high probability of failed differentiation results (e.g., no differentiation or differentiating unwanted tissue types). However, monitoring via microscopy is labor-intensive and time-consuming, and also has high inter-observer variation issues. Therefore, it significantly impedes the progression of stem cell research and clinical applications nowadays. In recent years, machine learning has shown promising results in many applications of artificial intelligence (AI) in different fields, especially computer vision and image analysis. AI-based computational tool will bring benefits like high-throughput, high accuracy, and reproductivity in many medical applications. In stem cell culture and differentiation, we believe that applying this new technology will help researcher detect abnormal stem cell differentiation at the early stage via microscopy to save time, labor, and cost for the study and aggregate reproducible data along the process. To this end, we developed a machine learning-based AI model to assist in monitoring morphological changes of hESCs culture in bright-field microscopy images obtained from different differentiation stages to mature hepatocytes. We conducted a pilot study to train an AI model estimating efficiency of stem cell differentiation at Hepatic Progenitor Cell (HPC) stage, which is a critical checkpoint for hepatocyte differentiation. To prepare datasets for training, experienced researchers annotated the morphology of HPC in hundreds of microscope images and determined a differentiation result (success/fail) for every image. During the model training, the initial model was first trained by a training dataset consisting of 341 success and 366 fail HPC results. Subsequently, a smaller separate dataset comprising of 86 success and 51 fail HPC results was then used for cross-validation. Finally, the test set containing 64 success and 29 fail HPC results was used to evaluate the AI model performance. In result, the AI model presented an excellent performance (accuracy= 0.978 and F1 score= 0.975). Our study suggests a potential application of AI-assisted monitoring model for stem cell culture and differentiation in the future. Citation Format: Wei-Lei Yang, Zijun Huo, ShihYu Chen, Dandan Zhu, Tien-Jen Liu, Dung-Fang Lee. Monitoring of stem cell differentiation to mature hepatocytes with a machine learning-based AI model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 185.
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185:基于机器学习的AI模型监测干细胞向成熟肝细胞的分化
基于人类胚胎干细胞(hESCs)和多能干细胞(iPSCs)的疾病建模是癌症研究和开发新的癌症治疗方法的潜在平台。干细胞的分化是这些疾病模型的必要步骤。对于组织特异性分化,hESCs或iPSCs在特定的诱导和分化培养基中培养,形成不同类型的组织细胞,如肌肉、皮肤和肝脏,为进一步的研究或临床应用提供依据。在谱系分化过程中,研究者需要在显微镜下通过检查细胞形态学变化来密切监测干细胞的分化是否进入正轨,因为这一过程很可能导致分化失败的结果(如没有分化或分化不需要的组织类型)。然而,通过显微镜进行监测是劳动密集型和耗时的,而且观察者之间也有很高的差异问题。因此,它严重阻碍了当今干细胞研究和临床应用的进展。近年来,机器学习在人工智能(AI)在不同领域的许多应用中显示出可喜的成果,尤其是计算机视觉和图像分析。基于人工智能的计算工具将在许多医疗应用中带来高通量、高精度和可重复性等优点。在干细胞培养和分化中,我们相信应用这项新技术将有助于研究人员通过显微镜在早期阶段检测异常干细胞分化,从而节省研究的时间、劳动力和成本,并在整个过程中收集可重复的数据。为此,我们开发了一种基于机器学习的人工智能模型,以协助监测从不同分化阶段到成熟肝细胞的hESCs培养物在亮场显微镜下的形态学变化。我们进行了一项试点研究,以训练人工智能模型来估计肝祖细胞(HPC)阶段干细胞分化的效率,这是肝细胞分化的关键检查点。为了准备训练数据集,经验丰富的研究人员在数百张显微镜图像中注释了HPC的形态,并确定了每张图像的分化结果(成功/失败)。在模型训练过程中,首先使用由341个HPC成功和366个HPC失败结果组成的训练数据集对初始模型进行训练。随后,一个较小的独立数据集,包括86个成功和51个失败的HPC结果,然后用于交叉验证。最后,使用包含64个成功和29个失败的HPC结果的测试集来评估AI模型的性能。结果表明,该人工智能模型的准确率为0.978,F1得分为0.975。我们的研究表明,人工智能辅助监测模型在未来可能应用于干细胞培养和分化。引用格式:杨卫雷,霍子军,陈世赫,朱丹丹,刘天仁,李东芳。基于机器学习的AI模型监测干细胞向成熟肝细胞的分化[摘要]。见:美国癌症研究协会2021年年会论文集;2021年4月10日至15日和5月17日至21日。费城(PA): AACR;癌症杂志,2021;81(13 -增刊):185。
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