Functional Anatomy of the Inferior Longitudinal Fasciculus: From Historical Reports to Current Hypotheses

Herbet, Guillaume; Zemmoura, Ilyess; Duffau, Hugues

doi:10.3389/fnana.2018.00077

Cited by 236 publications

(195 citation statements)

References 140 publications

(166 reference statements)

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“…We also observed rapid increases in FC of the inferior longitudinal fasciculi, which may be related to higher-order visual, emotional and reading capabilities (Herbet et al, 2018).…”

Section: Cognitive-behavioral and Functional Relevancementioning

confidence: 58%

Early childhood development of white matter fiber density and morphology

Dimond

Rohr

Smith

et al. 2019

Preprint

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Early childhood is an important period for cognitive and brain development, though white matter changes specific to this period remain understudied. Here we utilize a novel analytic approach to quantify and track developmental changes in white matter micro-and macro-structure, calculated from individually oriented fiber-bundle populations, termed "fixels". Fixel-based analysis and mixed-effects models were used to assess tract-wise changes in fiber density and bundle morphology in 73 girls scanned at baseline (ages 4.09-7.02, mean=5.47, SD=0.81), 6-month (N=7), and one-year follow-up (N=42). For comparison, we also assessed changes in commonly utilized diffusion tensor metrics: fractional anisotropy (FA), and mean, radial and axial diffusivity (MD, RD, AD). Maturational increases in fixel-metrics were seen in most major white matter tracts, with the most rapid increases in the corticospinal tract and slowest or non-significant increases in the genu of the corpus callosum and uncinate fasciculi. As expected, we observed developmental increases in FA and decreases in MD, RD and AD, though percentage changes were smaller relative to fixel-metrics. The majority of tracts showed more substantial morphological than microstructural changes. These findings highlight early childhood as a period of dynamic white matter maturation, characterized by large increases in macroscopic fiber bundle size, mild changes in axonal density, and parallel, albeit less substantial, changes in diffusion tensor metrics.

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“…We also observed rapid increases in FC of the inferior longitudinal fasciculi, which may be related to higher-order visual, emotional and reading capabilities (Herbet et al, 2018).…”

Section: Cognitive-behavioral and Functional Relevancementioning

confidence: 58%

Early childhood development of white matter fiber density and morphology

Dimond

Rohr

Smith

et al. 2019

Preprint

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“…The progression from unimodal perceptual representations to multimodal conceptual representations occurs in a graded fashion across many cortical areas 55,58 corresponding well to a deep network. Long-distance white matter tracts, such as the inferior longitudinal fasciculus 59 , traverse temporal cortex, providing pathways for sparse shortcut connectivity. Recent evidence suggests specifically that posterior fusiform connects to the ATL both via gradual progression along the anterior fusiform and a ‘direct’ white matter route 60 .…”

Section: Discussionmentioning

confidence: 99%

Reverse-Engineering the Cortical Architecture for Controlled Semantic Cognition

Jackson

Rogers

Ralph

2019

Preprint

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We present a ‘reverse engineering’ approach to deconstruct cognition into neurocomputational mechanisms and their underlying cortical architecture, using controlled semantic cognition as a test case. By systematically varying the structure of a computational model and assessing the functional consequences, we identified architectural properties necessary for generating the core functions of the semantic system. Semantic cognition presents a challenging test case as the brain must achieve two seemingly contradictory functions: abstracting context-invariant conceptual representations across time and modalities, whilst producing specific context-sensitive behaviours appropriate for the immediate task. These functions were best achieved in models possessing a single, deep multimodal hub with sparse connections from modality-specific inputs, and control systems acting on peripheral rather than deep network layers. These architectural features correspond well with those suggested by neural data, strongly supporting the efficacy of the reverse engineering approach, and further generating novel hypotheses about the neuroanatomy of controlled semantic cognition.

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“…The ILF, which connects ventral aspects of ATL, occipito-temporal, and occipital cortex (Herbet et al, 2018), appears critical for bidirectional interactions between an ATL-based bilateral semantic ‘hub’ and representations supported by occipital and middle/posterior temporal regions (Patterson et al, 2007; Lambon Ralph et al, 2017; Chen et al, 2017). In addition to demonstrations of altered ILF microstructure in semantic dementia (Agosta et al, 2010), recent studies report associations between ILF microstructure and individual differences in semantic learning (Ripollés et al, 2017) and memory (Hodgetts et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

“…Here, we used multi-shell diffusion MRI and spherical deconvolution tractography to investigate whether individual differences in ILF and fornix microstructure would be associated with individual differences in trait curiosity. Given the importance of ILF to semantic cognition (Hodgetts et al, 2017; Ripollés et al, 2017; Herbet et al, 2018), we predicted an association between ILF microstructure and EC but not PC. In contrast, given that hippocampal circuitry supports novelty detection, exploratory behaviour and information seeking in many domains (O’Keefe and Nadel, 1978; Kumaran and Maguire, 2009; Murray et al, 2017; Voss et al, 2017) we predicted an association between fornix microstructure and both EC and PC.…”

Section: Introductionmentioning

confidence: 96%

“…Studies investigating higher-order personality traits subsuming curiosity, however, provide a fruitful starting point to investigate the neuroanatomical connections underlying trait curiosity (DeYoung, 2014; Woo et al, 2014). For example, Privado et al (2017) found an association between ‘openness to experience’ and microstructure of the inferior longitudinal fasciculus (ILF), a ventral, temporo-occipital association tract implicated in semantic memory (Herbet et al, 2018; Hodgetts et al, 2015, 2017). Additionally, Cohen et al (2009) showed that individual differences in novelty seeking were associated with microstructure of the fornix, a key pathway that connects the hippocampus - involved in novelty detection, exploration, information seeking and episodic memory (O’Keefe and Nadel, 1978; Kumaran and Maguire, 2009; Murray et al, 2017; Voss et al, 2017) - to the thalamus, ventral striatum, amygdala and prefrontal cortex (Saunders and Aggleton, 2007; Aggleton et al 2015).…”

Section: Introductionmentioning

confidence: 99%

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White matter pathways supporting individual differences in epistemic and perceptual curiosity

Valji

Priemysheva

Hodgetts

et al. 2019

Preprint

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1 Across the lifespan, curiosity motivates us to learn, yet curiosity varies strikingly between 2 individuals. Such individual differences have been shown for two distinct dimensions of 3 curiosity: epistemic curiosity (EC), the desire to acquire knowledge about facts, and 4 perceptual curiosity (PC), the desire for sensory information. It is not known, however, 5 whether both dimensions of curiosity depend on different brain networks and whether inter-6 individual differences in curiosity depend on variation in anatomical connectivity within these 7 networks. Here, we investigated the neuroanatomical connections underpinning individual 8 variation in trait curiosity. Fifty-one female participants underwent a two-shell diffusion MRI 9 sequence and completed questionnaires measuring EC and PC. Using deterministic 10 spherical deconvolution tractography we extracted microstructural metrics (fractional 11 anisotropy (FA) and mean diffusivity (MD)) from two key white matter tracts: the fornix 12 (implicated in novelty processing, exploration, information seeking and episodic memory) 13 and the inferior longitudinal fasciculus (ILF) (implicated in semantic learning and memory). In 14 line with our predictions, we found that EC -but not PC -correlated with ILF microstructure. 15Fornix microstructure, in contrast, correlated with both EC and PC with posterior 16 hippocampal fornix fibres -associated with posterior hippocampal network connectivity -17 linked to PC specifically. These findings suggest that differences in distinct dimensions of 18 curiosity map systematically onto specific white matter tracts underlying well characterized 19 brain networks. Furthermore, the results pave the way to study the anatomical substrates of 20 inter-individual differences in dimensions of trait curiosity that motivate the learning of 21 distinct forms of knowledge and skills. 22 Significance statement 23Despite recent interest in curiosity states and the broad spectrum of variation in stable 24 tendencies to experience or express curiosity, the biological correlates of trait curiosity are 25 unknown. Here, we found that specific types of curiosity correlate with microstructure of 26 specific white matter tracts in the brain -the inferior longitudinal fasciculus and the fornix. 27Our findings on the relationship between specific aspects of curiosity and anatomical 28 connections underlying well characterized brain networks highlight the specificity of trait 29 curiosity. Furthermore, our findings pave the way to further understand inter-individual 30 differences in curiosity and which aspects of curiosity benefit language, memory and other 31 cognitive processes cultivating a deeper knowledge and skill set. 32 4 Introduction 33Curiosity is described as the desire for new information that motivates seeking out and 34 acquiring knowledge (Loewenstein, 1994; Litman, 2005). The momentary experience of 35 curiosity can be seen as a motivational state that facilitates knowledge acquisition (Silvia & 36 Kashdan, 2009; Gottlieb and Oudeyer,...

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Functional Anatomy of the Inferior Longitudinal Fasciculus: From Historical Reports to Current Hypotheses

Cited by 236 publications

References 140 publications

Early childhood development of white matter fiber density and morphology

Early childhood development of white matter fiber density and morphology

Reverse-Engineering the Cortical Architecture for Controlled Semantic Cognition

White matter pathways supporting individual differences in epistemic and perceptual curiosity

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