Effects of adaptation on numerosity decoding in the human brain

Castaldi, Elisa; Aagten-Murphy, David; Tosetti, Michela; Burr, David; Morrone, Maria Concetta

doi:10.1016/j.neuroimage.2016.09.020

Cited by 63 publications

(75 citation statements)

References 65 publications

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“…While this strategy is commonly used in studies on numerosity perception, it does not control for differences in the total amount and distribution of contrast energy across numerosities, which is likely to affect early visual responses. This factor may indeed likely account for the early visual cortex activation results in this and other studies, also potentially suggested by a previous fMRI study on numerosity perception, which, after equating the contrast energy of the stimuli, could successfully decode numerosity in parietal but not early visual cortex (Castaldi et al, 2016).…”

Section: Separate Representational Codes For Number and Lengthsupporting

confidence: 72%

Processing number and length in the parietal cortex: Sharing resources, not a common code

Borghesani

Hevia

Viarouge

et al. 2019

Cortex

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A current intense discussion in numerical cognition concerns the relationship between the processing of numerosity and other non-numerical quantities. In particular, it is a matter of debate whether number and other quantities (e.g., size, length) are represented separately in the brain or whether they share a common generalized magnitude representation. We acquired high-resolution functional MRI data while adult subjects engaged in a magnitude comparison task involving either numerosity (i.e., which of the two sets has more elements?) or line length (i.e., which of the two lines is longer?). We compared the activation evoked by the two different types of quantity and observed a common recruitment of a vast portion of occipital and parietal cortices. Using MVPA, we demonstrated that some of the commonly activated regions represented the discrete and continuous quantities via a similar distance-dependent magnitude code. However, we found no effect of distance across the two quantity representations, failing to support the existence of a common, dimension invariant, generalized quantity code. Taken together, these findings indicate that although the processing of number and length is supported by partially overlapping neural resources, representations within these regions do not appear to be based on a common neural code.

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Section: Separate Representational Codes For Number and Lengthsupporting

confidence: 72%

Processing number and length in the parietal cortex: Sharing resources, not a common code

Borghesani

Hevia

Viarouge

et al. 2019

Cortex

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“…However, independent of the execution of such numerical operations, enhanced activity for numbers as opposed to letters or colors was also to a lesser extent measured in HIPS during an orthogonal target detection task (Eger et al, 2003). Moreover, parietal regions were reported to habituate to repeated presentation of the same numerical quantity and show numerical distance-dependent recovery of activity for deviant numbers Cantlon et al, 2006;Ansari et al, 2006b) to some extent even across formats (Piazza et al, 2007;Vogel et al, 2017), to encode numerical quantity in multi-voxel patterns of evoked activity (Borghesani et al, 2018;Bulthé et al, 2014;Castaldi et al, 2016Castaldi et al, , 2019Cavdaroglu and Knops, 2018;Damarla and Just, 2013;Eger et al, 2009Eger et al, , 2015Lasne et al, 2018) and to contain topographically organized numerosity maps (Harvey et al, 2013;Dumoulin, 2017a, 2017b).…”

Section: Introductionmentioning

confidence: 97%

Mapping numerical perception and operations in relation to functional and anatomical landmarks of human parietal cortex

Castaldi

Vignaud

Eger

2019

Preprint

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Human functional imaging has identified the middle part of the intraparietal sulcus (IPS) as an important brain substrate for different types of numerical tasks. This area is often equated with the macaque ventral intraparietal area (VIP) where neuronal selectivity for non-symbolic numbers is found. However, the low spatial resolution and whole-brain averaging analysis performed in most fMRI studies limit the extent to which an exact correspondence of activation in different numerical tasks with specific sub-regions of the IPS can be established.Here we disentangled the functional neuroanatomy of numerical perception and operations (comparison and calculation) by acquiring high-resolution 7T fMRI data in a group of human adults, and relating the activations in different numerical contrasts to anatomical and functional landmarks on the cortical surface. Our results reveal a functional heterogeneity within human intraparietal cortex where the visual field map representations in superior/medial parts of IPS and superior parietal gyrus are involved predominantly in numerosity perception, whereas numerical operations predominantly recruit lateral/inferior parts of IPS. Since calculation and comparison-related activity fell mainly outside the field map representations considered the functional equivalent of the monkey VIP/LIP complex, the areas most activated during such numerical operations in humans are likely different from VIP.

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“…Hence, common BOLD increase in numerical tasks does not necessarily imply that the underlying representation for different formats and modes is the same. Yet, human imaging studies using multi-voxel pattern analysis (MVPA) endorse simultaneous numerosity encoding independent of response/task related processing (Bulthé et al, 2014;Castaldi et al, 2016;Dormal et al, 2010;Eger et al, 2013Eger et al, , 2009). Based on BOLD signal patterns from PPC these authors were able to decode the numerosities seen by the participants using MVPA.…”

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confidence: 99%

Evidence for a Posterior Parietal Cortex Contribution to Spatial but not Temporal Numerosity Perception

Cavdaroglu

Knops

2018

Cerebral Cortex

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Posterior parietal cortex (PPC) is thought to encode and represent the number of objects in a visual scene (i.e., numerosity). Whether this representation is shared for simultaneous and sequential stimuli (i.e., mode independency) is debated. We tested the existence of a common neural substrate for the encoding of these modes using fMRI. While both modes elicited overlapping BOLD response in occipital areas, only simultaneous numerosities significantly activated PPC. Unique activation for sequential numerosities was found in bilateral temporal areas. Multivoxel pattern analysis revealed numerosity selectivity in PPC only for simultaneous numerosities and revealed differential encoding of presentation modes. Voxel-wise numerosity tuning functions for simultaneous numerosities in occipital and parietal ROIs revealed increasing numerosity selectivity along an occipito-to-parietal gradient. Our results suggest that the parietal cortex is involved in the extraction of spatial but not temporal numerosity and question the idea of commonly used cortical circuits for a mode-independent numerosity representation.

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Effects of adaptation on numerosity decoding in the human brain

Cited by 63 publications

References 65 publications

Processing number and length in the parietal cortex: Sharing resources, not a common code

Processing number and length in the parietal cortex: Sharing resources, not a common code

Mapping numerical perception and operations in relation to functional and anatomical landmarks of human parietal cortex

Evidence for a Posterior Parietal Cortex Contribution to Spatial but not Temporal Numerosity Perception

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