Integrating brain function and structure in the study of the human attentional networks: a functionnectome study
Identificadores
URI: https://hdl.handle.net/10481/93059Metadatos
Mostrar el registro completo del ítemAutor
Martín Signes, Mar; Paz-Alonso, Pedro M.; Thiebaut de Schotten, Michel; Chica Martínez, Ana BelénEditorial
Springer Nature
Materia
Attention Phasic alerting Spatial orienting Executive attention fMRI White matter
Fecha
2024-07-06Referencia bibliográfica
Martín-Signes, M., Paz-Alonso, P. M., Thiebaut de Schotten, M., & Chica, A. B. (2024). Integrating brain function and structure in the study of the human attentional networks: a functionnectome study. Brain Structure and Function, 1-15.
Resumen
Attention is a heterogeneous function theoretically divided into different systems. While functional magnetic resonance
imaging (fMRI) has extensively characterized their functioning, the role of white matter in cognitive function has gained
recent interest due to diffusion-weighted imaging advancements. However, most evidence relies on correlations between
white matter properties and behavioral or cognitive measures. This study used a new method that combines the signal from
distant voxels of fMRI images using the probability of structural connection given by high-resolution normative tractog-
raphy. We analyzed three fMRI datasets with a visual perceptual task and three attentional manipulations: phasic alerting,
spatial orienting, and executive attention. The phasic alerting network engaged temporal areas and their communication
with frontal and parietal regions, with left hemisphere dominance. The orienting network involved bilateral fronto-parietal
and midline regions communicating by association tracts and interhemispheric fibers. The executive attention network
engaged a broad set of brain regions and white matter tracts connecting them, with a particular involvement of frontal
areas and their connections with the rest of the brain. These results partially confirm and extend previous knowledge on
the neural substrates of the attentional system, offering a more comprehensive understanding through the integration of
structure and function.