Ordinal Classification with Distance Regularization for Robust Brain Age Prediction.

Jay Shah, Md Mahfuzur Rahman Siddiquee, Yi Su, Teresa Wu, Baoxin Li
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Abstract

Age is one of the major known risk factors for Alzheimer's Disease (AD). Detecting AD early is crucial for effective treatment and preventing irreversible brain damage. Brain age, a measure derived from brain imaging reflecting structural changes due to aging, may have the potential to identify AD onset, assess disease risk, and plan targeted interventions. Deep learning-based regression techniques to predict brain age from magnetic resonance imaging (MRI) scans have shown great accuracy recently. However, these methods are subject to an inherent regression to the mean effect, which causes a systematic bias resulting in an overestimation of brain age in young subjects and underestimation in old subjects. This weakens the reliability of predicted brain age as a valid biomarker for downstream clinical applications. Here, we reformulate the brain age prediction task from regression to classification to address the issue of systematic bias. Recognizing the importance of preserving ordinal information from ages to understand aging trajectory and monitor aging longitudinally, we propose a novel ORdinal Distance Encoded Regularization (ORDER) loss that incorporates the order of age labels, enhancing the model's ability to capture age-related patterns. Extensive experiments and ablation studies demonstrate that this framework reduces systematic bias, outperforms state-of-art methods by statistically significant margins, and can better capture subtle differences between clinical groups in an independent AD dataset. Our implementation is publicly available at https://github.com/jaygshah/Robust-Brain-Age-Prediction.

利用距离正则化的序数分类法进行可靠的脑年龄预测
年龄是阿尔茨海默病(AD)的主要已知风险因素之一。早期发现阿尔茨海默病对于有效治疗和防止不可逆转的脑损伤至关重要。脑年龄是从反映衰老引起的结构变化的脑成像中得出的一种测量指标,它可能具有识别阿尔茨海默病发病、评估疾病风险和计划有针对性的干预措施的潜力。基于深度学习的回归技术从磁共振成像(MRI)扫描中预测脑年龄,最近已显示出很高的准确性。然而,这些方法受制于固有的平均回归效应,这会造成系统性偏差,导致高估年轻受试者的脑年龄,低估老年受试者的脑年龄。这就削弱了预测脑年龄作为下游临床应用的有效生物标志物的可靠性。在这里,我们将脑年龄预测任务从回归重新表述为分类,以解决系统性偏差问题。我们认识到保留年龄的顺序信息对于理解衰老轨迹和纵向监测衰老的重要性,因此提出了一种新的ORdinal Distance Encoded Regularization(ORDER)损失,它包含了年龄标签的顺序,增强了模型捕捉年龄相关模式的能力。广泛的实验和消融研究表明,这一框架减少了系统性偏差,在统计学上显著优于最先进的方法,并能更好地捕捉独立的注意力缺失症数据集中临床组之间的细微差别。我们的实现方法可在 https://github.com/jaygshah/Robust-Brain-Age-Prediction 公开获取。
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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