AbstractBackgroundAccumulation of pathology in cortical tissue are early pathological hallmarks of Alzheimer’s disease. High resolution T1w/T2w ratio maps from structural MRI may reflect tissue microstructure with sensitivity to myelin, iron, and dendritic density. Few studies have investigated this in AD with conflicting reports of directionality of T1w/T2w ratios in individuals with AD diagnosis and pathology. However, these ratios will be sensitive to pulse sequences, protocols and bias field inhomogeneities, limiting their utility in clinical and research contexts. Here we employ R1 (=1/T1) relaxometry mapping, a quantitative imaging measure that is sensitive to myelin, to investigate relationships between cortical and subcortical tissue microstructure, age, AD diagnosis, and amyloid and tau pathology.MethodParticipants from the Wisconsin Alzheimer’s Disease Research Center and Wisconsin Registry for Alzheimer’s Prevention underwent 3T MRI with whole‐brain, 1mm isotropic MPnRAGE T1 relaxometry with motion correction (Kecskemeti et al., 2016) (N=605/CN, 39/AD; age = 65.49 +/‐ 7.89 yrs) with a subset undergoing lumbar puncture for CSF Aß42/Tau biomarker classification (N = 141/A‐T‐, 26/A+T‐, 22/A‐T+, 18/A+T+). T1‐weighted images were processed using ANTS and CAT12, and transformation warps were applied to produce subcortical R1 maps in MNI space (6mm smoothing) and cortical R1 surface meshes (164k mesh, 5mm smoothing). Vertex‐wise (GM) and voxel‐wise (WM) ANCOVA were performed (p<0.05 FWE corrected). Covariates included age, sex, study protocol, and AD diagnosis in model 1, and age, sex, years between CSF collection and MRI, study protocol, and A/T biomarker group in model 2.ResultSignificant associations between R1 and age, clinical AD diagnosis, and A/T pathology were found (Figure 1A‐C). Post‐hoc tests revealed increased R1 due to A/T pathology driven by A+T+ individuals. In contrast, significant widespread decreases in subcortical R1 were found with age and AD diagnosis (Figure 1D&E), with no significant alterations in subcortical R1 due to biomarker status.ConclusionCortical and subcortical tissue exhibit differential tissue microstructural changes in response to aging, AD diagnosis and pathology. Importantly, increases in cortical R1 in unimpaired A+T+ individuals may reflect increased remyelination prior to the development of cognitive impairment. Future research will assess longitudinal relationships of R1 with age, cognition and markers of neurodegeneration.