The context-contingent nature of cross-modal activations of the visual cortex

Matusz, Paweł J.; Retsa, Chrysa; Murray, Micah M.

doi:10.1016/j.neuroimage.2015.11.016

Cited by 34 publications

(44 citation statements)

References 94 publications

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“…Indeed, we describe similar connectivity increases but at the indirect connectivity level, meaning that a significant amount of cross-modal interactions between visual cortex and other primary systems is likely determined by multimodal relay stations. Furthermore, we theorize that functional connectivity decreases between the occipital lobe and other primary systems in blind adults (14,15) may relate to impaired connections between primary visual areas and the multimodal integration network and that-potentially as an adaptive phenomenon-increased connectivity between somatosensory or auditory cortices and multimodal areas develop (both phenomena seen in our findings).…”

Section: Discussionmentioning

confidence: 59%

“…Historically, the visual cortex was considered to be exclusively devoted to visual processes, but there is now evidence that activity within the human visual cortex plays an active role in multisensory processes (14,15). In recent years, the occipital cortex, as well as adjacent ventral areas such as the fusiform gyrus (16,17), have been the main regions of interest in the study of cross-modal phenomena in blindness.…”

Section: Discussionmentioning

confidence: 99%

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Brain circuit–gene expression relationships and neuroplasticity of multisensory cortices in blind children

Ortiz-Terán

Diez

Ortiz

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Sensory deprivation reorganizes neurocircuits in the human brain. The biological basis of such neuroplastic adaptations remains elusive. In this study, we applied two complementary graph theory-based functional connectivity analyses, one to evaluate whole-brain functional connectivity relationships and the second to specifically delineate distributed network connectivity profiles downstream of primary sensory cortices, to investigate neural reorganization in blind children compared with sighted controls. We also examined the relationship between connectivity changes and neuroplasticity-related gene expression profiles in the cerebral cortex. We observed that multisensory integration areas exhibited enhanced functional connectivity in blind children and that this reorganization was spatially associated with the transcription levels of specific members of the cAMP Response Element Binding protein gene family. Using systems-level analyses, this study advances our understanding of human neuroplasticity and its genetic underpinnings following sensory deprivation.blindness | children | neuroplasticity | functional connectivity | CREB family N europlasticity is an intrinsic ability of the brain to modify and rewire itself following experiences (1). The study of neuroplastic reorganization in blind individuals offers a model through which neuroadaptive processes can be identified. For instance, cross-modal neuroplasticity is a mechanism by which blind individuals recruit visual-related cortices to process sensory information from other perceptual modalities (2-5). In addition to occipital regions, parietal and frontal multimodal integration regions of blind adults are capable of functional connectivity reorganization (6). These brain areas are part of a multimodal integration network that acts as a bridge integrating multisensory functions across cortical regions (7). Our group has previously characterized the hierarchical structure and central position of the multimodal integration network in adult blind subjects (6). Although this finding advances our understanding of how information from primary unimodal cortices is adaptively integrated into higher-order associative areas, it remains unclear if neuroplastic changes within multimodal integration areas also occur in blind children. Furthermore, in addition to clarifying the sites of prominent neuroplastic changes, the biological mechanisms through which neuroplastic alterations occur have yet to be fully elucidated in blind individuals.Concurrent advances in cellular and molecular biology and neuroimaging provide a unique opportunity to explore the interlinked relationships between genes and neural circuits (8). A neuroimaging endophenotype is informative because it is more closely related to the genetic end product than clinical or behavioral phenotypes (9). Thus, examining properties of systemslevel brain organization and cortical gene expression has great potential to expand our understanding of neuroplastic mechanisms, particularly if specific gene expression patt...

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Section: Discussionmentioning

confidence: 59%

Section: Discussionmentioning

confidence: 99%

Brain circuit–gene expression relationships and neuroplasticity of multisensory cortices in blind children

Ortiz-Terán

Diez

Ortiz

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

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“…In adults, neural attenuation for bimodal synchrony is thought to reflect more efficient processing and has been documented in both early sensory and later attentional responses (Belse et al, 2004;Pilling, 2009;van Wassenhove, Grant, & Poepple, 2005), whereas attenuation has only been observed in later going attentional responses in infants (Hyde et al, 2011, Grossmann et al, 2006Reynolds et al, 2014;Vogel et al, 2012). Inconsistencies in the functional brain response between different experimental contexts in infants should not be taken as a limitation of the work, as most current views of multimodal processing and intersensory perception in adults conclude that context has a large effect on how, when, and where the brain is engaged (e.g., van Atteveldt et al, 2014;Matusz, Retsa, & Murray, 2016;Murray, Lewkowicz, Amedi, & Wallace, 2016). However, the fact that neural attenuation for bimodal synchrony has been documented exclusively in later attentional processing in infants but often appears during earlier sensory processing in adults may reflect a genuine developmental difference between infants and adults in efficiency and time course.…”

Section: ----------------------------Insert Figure 3 About Here -----mentioning

confidence: 97%

Behavioral and Neural Foundations of Multisensory Face-Voice Perception in Infancy

Hyde

Flom

Porter

2016

Developmental Neuropsychology

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“…Nonetheless and first, it is now well established that visual areas such as the LOC and auditory areas such as the STC demonstrate multisensory convergence and integration (see, e.g., Matusz, Retsa, & Murray, 2016; Sarmiento, Matusz, Sanabria, & Murray, 2015; reviewed in Doehrmann & Naumer, 2008; Murray et al, 2016b; ten Oever et al, 2016). Second, microelectrode recordings in monkey posterior infero-temporal (IT) cortex, for which the LOC is considered to be the human homologue, as well as visual area V4, demonstrate selective delay-period responses on a delayed match-to-sample task for specific multisensory and unisensory pairings (e.g., Colombo & Gross, 1994; Gibson & Maunsell, 1997; Haenny, Maunsell, & Schiller, 1988; Maunsell, Sclar, Nealey, & DePriest, 1991; see also Goulet & Murray, 2001).…”

Section: Cognitive Mechanisms By Which Multisensory Contexts Impromentioning

confidence: 99%

A multisensory perspective on object memory

2017

Self Cite

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Traditional studies of memory and object recognition involved objects presented within a single sensory modality (i.e., purely visual or purely auditory objects). However, in naturalistic settings, objects are often evaluated and processed in a multisensory manner. This begets the question of how object representations that combine information from the different senses are created and utilised by memory functions. Here we review research that has demonstrated that a single multisensory exposure can influence memory for both visual and auditory objects. In an old/new object discrimination task, objects that were presented initially with a task-irrelevant stimulus in another sense were better remembered compared to stimuli presented alone, most notably when the two stimuli were semantically congruent. The brain discriminates between these two types of object representations within the first 100ms post-stimulus onset, indicating early “tagging” of objects/events by the brain based on the nature of their initial presentation context. Interestingly, the specific brain networks supporting the improved object recognition vary based on a variety of factors, including the effectiveness of the initial multisensory presentation and the sense that is task-relevant. We specify the requisite conditions for multisensory contexts to improve object discrimination following single exposures, and the individual differences that exist with respect to these improvements. Our results shed light onto how memory operates on the multisensory nature of object representations as well as how the brain stores and retrieves memories of objects.

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The context-contingent nature of cross-modal activations of the visual cortex

Cited by 34 publications

References 94 publications

Brain circuit–gene expression relationships and neuroplasticity of multisensory cortices in blind children

Brain circuit–gene expression relationships and neuroplasticity of multisensory cortices in blind children

Behavioral and Neural Foundations of Multisensory Face-Voice Perception in Infancy

A multisensory perspective on object memory

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