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Reorganisation of cortical oscillatory dynamics underlying disinhibition in frontotemporal dementia

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The distribution of pathology in frontotemporal dementia is anatomically selective, to distinct cortical regions and with differential neurodegeneration across the cortical layers. The cytoarchitecture and connectivity of cortical laminae preferentially supports frequency-specific oscillations and hierarchical information transfer between brain regions. We therefore predicted that in frontotemporal dementia, core functional deficits such as disinhibition would be associated with differences in the frequency spectrum and altered cross-frequency coupling between frontal cortical regions. We examined this hypothesis using a “Go-NoGo” response inhibition paradigm with eighteen patients with behavioural variant frontotemporal dementia and 20 healthy aged-matched during magnetoencephalography. During Go and NoGo trials, beta desynchronisation was severely attenuated in patients. Beta power was associated with increased impulsivity, as measured by the Cambridge Behavioural Inventory, a carer based questionnaire of changes in everyday behaviour. To quantify the changes in cross-frequency coupling in the frontal lobe, we used Dynamic Causal Modeling to test a family of hierarchical casual models, which included the inferior frontal gyrus, pre-supplementary motor area (preSMA) and primary motor cortex. This analysis revealed evidence for cross-frequency coupling in a fully connected network in both groups. However, in the patient group, we identified a significant loss of reciprocal connectivity of the inferior frontal gyrus, particularly for interactions in the gamma band and for theta to alpha coupling. Importantly, although prefrontal coupling was diminished, gamma connectivity between preSMA and motor cortex was enhanced in patients. We propose that the disruption of behavioural control arises from reduced frequency-specific connectivity of the prefrontal cortex, together with a hyper-synchronous reorganisation of connectivity among preSMA and motor regions. These results are supported by preclinical evidence of the selectivity of frontotemporal lobar degeneration on oscillatory dynamics, and provide a clinically relevant yet precise neurophysiological signature of behavioural control as a potential pharmacological target for early phase experimental medicines studies.



frontotemporal dementia,, magnetoencephalography, response inhibition, cross-frequency coupling, beta desynchronization

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Brain: a Journal of Neurology

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Oxford University Press
Wellcome Trust (103838/Z/14/Z)
Medical Research Council (MC_U105597119)
Cambridge University Hospitals NHS Foundation Trust (CUH) (146281)
Medical Research Council (G1000183)
Wellcome Trust (093875/Z/10/Z)
Medical Research Council (G1100464)
Medical Research Council (MR/M009041/1)
Medical Research Council (MR/M024873/1)
Medical Research Council (G0001354)
Medical Research Council (MC_UU_00005/12)
Medical Research Council (G1100464/1)
This work was primarily funded by the Wellcome Trust (103838) with additional support from the Medical Research Council (MC-A060-5PQ30, and RG62761) and the NIHR Cambridge Biomedical Research Centre and Cambridge Brain Bank. The BCNI is supported by a joint award from the Wellcome Trust and Medical Research Council.