Evidencing a place for the hippocampus within the core scene processing network

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Evidencing a place for the hippocampus within the core scene processing network. / Hodgetts, Carl; Shine, Jonathon; Lawrence, Andrew et al.
In: Human Brain Mapping, Vol. 37, 11.2016, p. 3779–3794.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Hodgetts, C, Shine, J, Lawrence, A, Downing, P & Graham, K 2016, 'Evidencing a place for the hippocampus within the core scene processing network', Human Brain Mapping, vol. 37, pp. 3779–3794. https://doi.org/10.1002/hbm.23275

APA

Hodgetts, C., Shine, J., Lawrence, A., Downing, P., & Graham, K. (2016). Evidencing a place for the hippocampus within the core scene processing network. Human Brain Mapping, 37, 3779–3794. https://doi.org/10.1002/hbm.23275

CBE

Hodgetts C, Shine J, Lawrence A, Downing P, Graham K. 2016. Evidencing a place for the hippocampus within the core scene processing network. Human Brain Mapping. 37:3779–3794. https://doi.org/10.1002/hbm.23275

MLA

VancouverVancouver

Hodgetts C, Shine J, Lawrence A, Downing P, Graham K. Evidencing a place for the hippocampus within the core scene processing network. Human Brain Mapping. 2016 Nov;37:3779–3794. Epub 2016 Oct 6. doi: 10.1002/hbm.23275

Author

Hodgetts, Carl ; Shine, Jonathon ; Lawrence, Andrew et al. / Evidencing a place for the hippocampus within the core scene processing network. In: Human Brain Mapping. 2016 ; Vol. 37. pp. 3779–3794.

RIS

TY - JOUR

T1 - Evidencing a place for the hippocampus within the core scene processing network

AU - Hodgetts, Carl

AU - Shine, Jonathon

AU - Lawrence, Andrew

AU - Downing, Paul

AU - Graham, Kim

N1 - Contract grant sponsor: BBSRC; Contract grant number: BB/ I007091/1 (KSG & PED); Contract grant sponsor: MRC; Contract grant number: G1002149 (KSG & CJH); Contract grant sponsor: Welsh Assembly Government (KSG) and Wales Institute of Cognitive Neuroscience

PY - 2016/11

Y1 - 2016/11

N2 - Functional neuroimaging studies have identified several “core” brain regions that are preferentially activated by scene stimuli, namely posterior parahippocampal gyrus (PHG), retrosplenial cortex (RSC), and transverse occipital sulcus (TOS). The hippocampus (HC), too, is thought to play a key role in scene processing, although no study has yet investigated scene‐sensitivity in the HC relative to these other “core” regions. Here, we characterised the frequency and consistency of individual scene‐preferential responses within these regions by analysing a large dataset (n = 51) in which participants performed a one‐back working memory task for scenes, objects, and scrambled objects. An unbiased approach was adopted by applying independently‐defined anatomical ROIs to individual‐level functional data across different voxel‐wise thresholds and spatial filters. It was found that the majority of subjects had preferential scene clusters in PHG (max = 100% of participants), RSC (max = 76%), and TOS (max = 94%). A comparable number of individuals also possessed significant scene‐related clusters within their individually defined HC ROIs (max = 88%), evidencing a HC contribution to scene processing. While probabilistic overlap maps of individual clusters showed that overlap “peaks” were close to those identified in group‐level analyses (particularly for TOS and HC), inter‐individual consistency varied across regions and statistical thresholds. The inter‐regional and inter‐individual variability revealed by these analyses has implications for how scene‐sensitive cortex is localised and interrogated in functional neuroimaging studies, particularly in medial temporal lobe regions, such as the HC.

AB - Functional neuroimaging studies have identified several “core” brain regions that are preferentially activated by scene stimuli, namely posterior parahippocampal gyrus (PHG), retrosplenial cortex (RSC), and transverse occipital sulcus (TOS). The hippocampus (HC), too, is thought to play a key role in scene processing, although no study has yet investigated scene‐sensitivity in the HC relative to these other “core” regions. Here, we characterised the frequency and consistency of individual scene‐preferential responses within these regions by analysing a large dataset (n = 51) in which participants performed a one‐back working memory task for scenes, objects, and scrambled objects. An unbiased approach was adopted by applying independently‐defined anatomical ROIs to individual‐level functional data across different voxel‐wise thresholds and spatial filters. It was found that the majority of subjects had preferential scene clusters in PHG (max = 100% of participants), RSC (max = 76%), and TOS (max = 94%). A comparable number of individuals also possessed significant scene‐related clusters within their individually defined HC ROIs (max = 88%), evidencing a HC contribution to scene processing. While probabilistic overlap maps of individual clusters showed that overlap “peaks” were close to those identified in group‐level analyses (particularly for TOS and HC), inter‐individual consistency varied across regions and statistical thresholds. The inter‐regional and inter‐individual variability revealed by these analyses has implications for how scene‐sensitive cortex is localised and interrogated in functional neuroimaging studies, particularly in medial temporal lobe regions, such as the HC.

KW - fuctional localiser

KW - fMRI

KW - Probabilistic overlap

KW - Medial temporal lobe

KW - Individual-level

KW - region of interest

U2 - 10.1002/hbm.23275

DO - 10.1002/hbm.23275

M3 - Article

VL - 37

SP - 3779

EP - 3794

JO - Human Brain Mapping

JF - Human Brain Mapping

SN - 1097-0193

ER -