Generating MRI-Derived CSF Proxy-Markers to Predict and Visualize Alzheimer's Disease Progression.
Anees Abrol, Vince D Calhoun, Alzheimer's Disease Neuroimaging Initiative
Abstract
Open AccessPreclinical detection of Alzheimer's disease (AD) is crucial to efficiently recruit clinical trial participants for examining AD-modifying drugs and ultimately yield clinical benefits for at-risk individuals. Cerebral amyloidosis precedes synaptic dysfunction and neurodegeneration markers, followed by the onset of AD-related cognitive impairment. To improve early AD-biomarker detection accuracy, patient data is, however, often collected via invasive procedures such as a lumbar puncture or intravenous injection of active radiopharmaceuticals. This coupled health risk is small yet significant and can be avoided by generating equally predictive or superior AD-risk staging proxy biomarkers derived from noninvasive neuroimaging modalities. In addition, using neuroimaging can provide richer insights into regional distributions of brain biomarkers of AD. Motivated by that, here we train neural networks to optimally generate latent structural MRI (sMRI) representations as proxies for cerebrospinal fluid (CSF) biomarker status on multiple classification and prediction contexts, an approach that we demonstrate has the potential to be clinically useful in screening and diagnosing AD and predicting AD progression. We found that the amygdala, hippocampus, parahippocampus, posterior and middle cingulate gyrus, middle and inferior temporal gyrus, angular gyrus, precuneus, and inferior parietal lobe regions revealed maximum attribution, thereby implying the highest prognostic value for AD risk. The proposed approach of predicting amyloid and/or tau pathology biomarkers from MRI data and subsequently transferring the MRI-derived amyloid and/or tau pathology models to predict future risk of AD progression may be useful to assist in disease screening, triage of patients for invasive testing, and efficiently determining suitability for clinical trial recruitment.