Non-linear development of brain morphometry in child and adolescent offspring of individuals with bipolar disorder or schizophrenia.

• Offspring of schizophrenia patients show deviating brain structure age trajectories. • Effects are strongest in mean cortical thickness and cerebral white matter volume. • Trajectories level off at the end of adolescence in schizophrenia offspring. • Divergences in trajectories remained after accounting for symptom severity scores. Offspring of parents with severe mental illness (e.g., bipolar disorder or schizophrenia) are at increased risk of developing psychopathology. Structural brain alterations have been found in child and adolescent offspring of patients with bipolar disorder and schizophrenia, but the developmental trajectories of brain anatomy in this high-familial-risk population are still unclear. 300 T1-weighted scans were obtained of 187 offspring of at least one parent diagnosed with bipolar disorder (n=80) or schizophrenia (n=53) and offspring of parents without severe mental illness (n=54). The age range was 8 to 23 years old; 113 offspring underwent two scans. Global brain measures and regional cortical thickness and surface area were computed. A generalized additive mixed model was used to capture non-linear age trajectories. Offspring of parents with schizophrenia had smaller total brain volume than offspring of parents with bipolar disorder (d =-0.20, p =0.004) and control offspring (d =-0.22, p =0.005) and lower mean cortical thickness than control offspring (d =-0.23, p <0.001). Offspring of parents with schizophrenia showed differential age trajectories of mean cortical thickness and cerebral white matter volume compared with control offspring (both p 's=0.003). Regionally, offspring of parents with schizophrenia had a significantly different trajectory of cortical thickness in the middle temporal gyrus versus control offspring (p <0.001) and bipolar disorder offspring (p =0.001), which was no longer significant after correcting for mean cortical thickness. These findings suggest that particularly familial high risk of schizophrenia is related to reductions and deviating developmental trajectories of global brain structure measures, which were not driven by specific regions. [ABSTRACT FROM AUTHOR]