Anterior Temporal Lobe Degeneration Produces Widespread Network-driven Dysfunction

Overview

Journal Brain

Publisher Oxford University Press

Specialty Neurology

Date 2013 Sep 28

PMID 24072486

Citations 103

Authors

Christine C Guo

Maria Luisa Gorno-Tempini

Benno Gesierich

Maya Henry

Andrew Trujillo

Tal Shany-Ur

Jorge Jovicich

Simon D Robinson

Joel H Kramer

Katherine P Rankin

Bruce L Miller

William W Seeley

Affiliations

Soon will be listed here.

Abstract

The neural organization of semantic memory remains much debated. A 'distributed-only' view contends that semantic knowledge is represented within spatially distant, modality-selective primary and association cortices. Observations in semantic variant primary progressive aphasia have inspired an alternative model featuring the anterior temporal lobe as an amodal hub that supports semantic knowledge by linking distributed modality-selective regions. Direct evidence has been lacking, however, to support intrinsic functional interactions between an anterior temporal lobe hub and upstream sensory regions in humans. Here, we examined the neural networks supporting semantic knowledge by performing a multimodal brain imaging study in healthy subjects and patients with semantic variant primary progressive aphasia. In healthy subjects, the anterior temporal lobe showed intrinsic connectivity to an array of modality-selective primary and association cortices. Patients showed focal anterior temporal lobe degeneration but also reduced physiological integrity throughout distributed modality-selective regions connected with the anterior temporal lobe in healthy controls. Physiological deficits outside the anterior temporal lobe correlated with scores on semantic tasks and with anterior temporal subregion atrophy, following domain-specific and connectivity-based predictions. The findings provide a neurophysiological basis for the theory that semantic processing is orchestrated through interactions between a critical anterior temporal lobe hub and modality-selective processing nodes.

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