Early prediction of cognitive impairment in adults aged 20 years and older using machine learning and biomarkers of heavy metal exposure

IF 2.9 Q2 TOXICOLOGY Current Research in Toxicology Pub Date : 2024-01-01 DOI:10.1016/j.crtox.2024.100198

Ali Nabavi , Farimah Safari , Mohammad Kashkooli , Sara Sadat Nabavizadeh , Hossein Molavi Vardanjani

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Abstract

Background

Cognitive impairment poses a growing health challenge as populations age. Heavy metals are implicated as environmental risk factors, but their role is not fully understood. Machine learning can integrate multi-factorial data to predict cognitive outcomes.

Objective

To develop and validate machine learning models for early prediction of cognitive impairment risk using demographics, clinical factors, and biomarkers of heavy metal exposure.

Method

A retrospective analysis was conducted using 2011–2014 NHANES data. Participants aged ≥ 20 underwent cognitive testing. Variables included demographics, medical history, lifestyle factors, and blood and urine levels of lead, cadmium, manganese, and other metals. Machine learning algorithms were trained on 90 % of data and evaluated on 10 %. Performance was assessed using metrics like accuracy, AUC, and sensitivity.

Result

A final sample of 2,933 participants was analyzed. The stacking ensemble model achieved the best performance with an AUC of 0.778 for test data, sensitivity of 0.879. Important predictors included age, gender, hypertension, education, urinary cadmium and blood manganese levels.

Conclusion

Machine learning can effectively predict cognitive impairment risk using comprehensive clinical and exposure data. Incorporating heavy metal biomarkers enhanced prediction and provided insights into environmental contributions to cognitive decline. Prospective studies are needed to validate models over time.

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利用机器学习和重金属暴露生物标志物早期预测 20 岁及以上成年人的认知功能障碍

背景随着人口老龄化，认知障碍对健康构成了日益严峻的挑战。重金属被认为是环境风险因素，但其作用尚未完全明了。目标利用人口统计学、临床因素和重金属暴露的生物标志物，开发并验证用于早期预测认知障碍风险的机器学习模型。方法利用 2011-2014 年 NHANES 数据进行回顾性分析。年龄≥20岁的参与者接受了认知测试。变量包括人口统计学、病史、生活方式因素以及血液和尿液中的铅、镉、锰和其他金属含量。机器学习算法在 90% 的数据上进行了训练，并在 10% 的数据上进行了评估。结果分析了 2,933 名参与者的最终样本。堆叠集合模型的性能最佳，测试数据的 AUC 为 0.778，灵敏度为 0.879。重要的预测因素包括年龄、性别、高血压、教育程度、尿镉和血锰水平。纳入重金属生物标志物可增强预测效果，并有助于深入了解环境对认知功能衰退的影响。随着时间的推移，需要进行前瞻性研究来验证模型。

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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