Right-Lateralized Maladaptive Topological Reorganization in Hyperthyroidism

Hyperthyroidism (HT) has been associated with cognitive impairments, but the structural connectomic and molecular mechanisms underlying these deficits remain poorly understood. In this study, we investigated large-scale brain network reorganization using structural connectivity derived from diffusion MRI in patients with 30 hyperthyroidism and 28 matched control participants. Subject level connectomes were analyzed to characterize network topology, with a specific focus on hub architecture, nodal alterations, and hemispheric reorganization. To probe molecular underpinnings, we integrated normative neurotransmitter receptor and transporter density maps with network metrics, assessing their correspondence to observed connectomic disruptions.

Individuals with hyperthyroidism exhibited increased structural connectivity, particularly in mid- and long-range connections, alongside disrupted network topology. These changes were characterized by reduced modularity, increased characteristic path length and hub reorganization, most prominently in subcortical and right-hemisphere regions. Importantly, network alterations were functionally relevant, as metrics showed significant associations with clinical and cognitive variables, including FT4 levels, BMI, and perceptuomotor performance in the hyperthyroid group. Spatial neuromolecular correspondence analyses further revealed that DAT, 5-HT2A, and NET were closely aligned with topological changes. Moreover, neurotransmitter-weighted within-module degree z-scores moderately predicted TSH levels in HT.

Our findings demonstrate that hyperthyroidism is associated with an increase in redundant, spatially extended white matter connections and a marked right-lateralized asymmetry in network organization. Furthermore, serotonergic (5-HT1a) and dopaminergic (DAT) systems consistently contributed to the modulation of intra-modular hubness, suggesting their role in maladaptive structural reorganization that may underlie perceptuomotor dysfunction in hyperthyroidism.